Veröffentlichungen am LH2

Lehrstuhl für Hydromechanik und Hydrosystemmodellierung

Dissertationen und Habilitationen

  1. 2022

    1. Michalkowski, C. (2022). Modeling water transport at the interface between porous GDL and gas distributor of a PEM fuel cell cathode. In Mitteilungen / Institut für Wasser- und Umweltsystemmodellierung, Universität Stuttgart (Dissertation Nr. 286, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung; Nummer 286). https://doi.org/10.18419/opus-12106

  2. 2021

    1. Ackermann, S. (2021). A multi-scale approach for drop/porous-medium interaction [Promotionsschrift, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. In Mitteilungsheft (Bd. 281). https://doi.org/10.18419/opus-11577
    2. Becker, B. (2021). Development of efficient multiscale multiphysics models accounting for reversible flow at various subsurface energy storage sites. In Mitteilungen / Institut für Wasser- und Umweltsystemmodellierung, Universität Stuttgart (Dissertation Nr. 284, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart; Nummer 284). https://doi.org/10.18419/opus-11753
    3. Seitz, G. (2021). Modeling fixed-bed reactors for thermochemical heat storage with the reaction system CaO/Ca(OH)2. In Mitteilungen / Institut für Wasser- und Umweltsystemmodellierung, Universität Stuttgart (Dissertation Nr. 278, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung; Nummer 278). https://doi.org/10.18419/opus-11522
    4. Heck, K. (2021). Modelling and analysis of multicomponent transport at the interface between free- and porous-medium flow - influenced by radiation and roughness [Promotionsschrift, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. In Mitteilungsheft (Bd. 280). https://doi.org/10.18419/opus-11635
    5. Emmert, S. (2021). Developing and calibrating a numerical model for microbially enhanced coal-bed methane production [Promotionsschrift, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. In Mitteilungsheft (Bd. 279). https://doi.org/10.18419/opus-11631

  3. 2020

    1. Koch, T. (2020). Mixed-dimension models for flow and transport processes in porous media with embedded tubular network systems [Dissertation, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung]. In Mitteilungen / Institut für Wasser- und Umweltsystemmodellierung, Universität Stuttgart (Bd. 274). https://doi.org/10.18419/opus-10975
    2. Weishaupt, K. (2020). Model concepts for coupling free flow with porous medium flow at the pore-network scale : from single-phase flow to compositional non-isothermal two-phase flow [Dissertation, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung]. In Mitteilungen / Institut für Wasser- und Umweltsystemmodellierung, Universität Stuttgart (Bd. 273). https://doi.org/10.18419/opus-10932
    3. Gläser, D. (2020). Discrete fracture modeling of multi-phase flow and deformation in fractured poroelastic media [Phdthesis, Stuttgart: Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. In Mitteilungen / Institut für Wasser- und Umweltsystemmodellierung, Universität Stuttgart (Bd. 275). http://dx.doi.org/10.18419/opus-11040

  4. 2019

    1. Schneider, M. (2019). Nonlinear finite volume schemes for complex flow processes and challenging grids [PhD Thesis, Stuttgart : Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. http://dx.doi.org/10.18419/opus-10416
    2. Beck, M. (2019). Conceptual approaches for the analysis of coupled hydraulic and geomechanical processes [Phdthesis, Stuttgart : Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. http://dx.doi.org/10.18419/opus-10418
    3. Haas, J. (2019). Optimal planning of hydropower and energy storage technologies for fully renewable power systems [Phdthesis, Stuttgart : Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. http://dx.doi.org/10.18419/opus-10297

  5. 2018

    1. Beck, M. (2018). Conceptual approaches for the analysis of coupled hydraulic and geomechanical processes [Promotionsschrift, Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. In Mitteilungsheft (Bd. 265). https://doi.org/10.18419/opus-10418
    2. Mejri, E. (2018). Modeling and Analysis of Salt Precipitation on Evaporation Processes in the Unsaturated Zone [Promotionsschrift]. Université de Tunis El Manar, Ecole Nationale d´Ingenieurs de Tunis.
    3. Bode, F. (2018). Early-warning monitoring systems for improved drinking water resource protection [Phdthesis, Stuttgart : Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. http://dx.doi.org/10.18419/opus-10268
    4. Fetzer, T. (2018). Coupled free and porous-medium flow processes affected by turbulence and roughness : models, concepts and analysis [Phdthesis, Stuttgart : Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart]. http://dx.doi.org/10.18419/opus-10016

  6. 2017

    1. Grüninger, C. (2017). Numerical coupling of Navier-Stokes and Darcy flow for soil-water evaporation (Bd. 253) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://doi.org/10.18419/opus-9657

  7. 2016

    1. Kissinger, A. (2016). Basin-Scale Site Screening and Investigation of Possible Impacts of CO2 Storage on Subsurface Hydrosystems (Bd. 251) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://dx.doi.org/10.18419/opus-8998
    2. Hommel, J. (2016). Modeling biogeochemical and mass transport processes in the subsurface: Investigation of microbially induced calcite precipitation (Bd. 244) [Promotionsschrift, Universität Stuttgart, TASK]. https://elib.uni-stuttgart.de/handle/11682/8787

  8. 2015

    1. Baber, K. (2015). Coupling free flow and flow in porous media in biological and technical applications: From a simple to a complex interface description (Bd. 236) [Promotionsschrift, Universität Stuttgart, TASK]. https://elib.uni-stuttgart.de/opus/volltexte/2015/9770/
    2. Schwenck, N. (2015). An XFEM-Based Model for Fluid Flow in Fractured Porous Media (Bd. 239) [Promotionsschrift, Universität Stuttgart, TASK]. https://elib.uni-stuttgart.de/opus/volltexte/2015/10017/
    3. Nuske, P. (2015). Beyond local equilibrium : relaxing local equilibrium assumptions in multiphase flow in porous media (Bd. 237) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2015/9796/pdf/thesisPhilippNuskeMerged.pdf

  9. 2014

    1. Lauser, A. (2014). Theory and Numerical Applications of Compositional Multi-Phase Flow in Porous Media (Bd. 228) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2014/9074/pdf/lauser_thesis_2print.pdf
    2. Mosthaf, K. (2014). Modeling and Analysis of Coupled Porous - Medium and Free Flow with Application to Evaporation Processes (Bd. 223) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2014/9064/pdf/DISSERTATION_KlausMosthaf_final.pdf
    3. Koch, J. (2014). Simulation, identification and characterization of contaminant source architectures in the subsurface (Bd. 233) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2014/9488/
    4. Eder, M. (2014). Climate sensitivity of a large lake (Bd. 226) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2014/8885/
    5. Faigle, B. (2014). Adaptive modelling of compositional multi-phase flow with capillary pressure. (Bd. 230) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2014/9068/
    6. Enzenhöfer, R. (2014). Risk quantification and management in water production and supply systems (Bd. 229) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2014/9015/
    7. Oladyshkin, S. (2014). Efficient modeling of environmental systems in the face of complexity and uncertainty (Bd. 231) [Habilitationsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2015/9523/pdf/Oladyshkin_HabilitationThesis.pdf

  10. 2013

    1. Tatomir, A. (2013). From discrete to continuum concepts of flow in fractured porous media (Bd. 212) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2013/8047/
    2. Flemisch, B. (2013). Tackling Coupled Problems in Porous Media: Development of Numerical Models and an Open Source Simulator [Habilitationsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2013/flemisch_habil.pdf
    3. Walter, L. (2013). Uncertainty Studies and Risk Assessment for CO2 Storage in Geological Formations (Bd. 221) [Promotionsschrift, Universität Stuttgart, TASK]. https://elib.uni-stuttgart.de/opus/volltexte/2013/8830/
    4. Greiner, P. (2013). Alkoholinjektion zur In-situ-Sanierung von CKW-Schadensherden in Grundwasserleitern: Charakterisierung der relevanten Prozesse auf unterschiedlichen Skalen (Bd. 227) [Promotionsschrift, Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung]. http://dx.doi.org/10.18419/opus-521
    5. Wolff, M. (2013). Multi-Scale Modeling of Two-Phase Flow in Porous Media Including Capillary Pressure Effects (Bd. 222) [Promotionsschrift, Universität Stuttgart, TASK]. https://elib.uni-stuttgart.de/opus/volltexte/2013/8661/
    6. Leube, P. (2013). Methods for Physically-Based Model Reduction in Time: Analysis, Comparison of Methods and Application (Bd. 224) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2013/8801/pdf/diss_final_Leube_bib_v2.pdf

  11. 2012

    1. Erbertseder, K. (2012). A multi-scale model for describing cancer-therapeutic transport in the human lung (Bd. 213) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2012/7200/
    2. Darcis, M. (2012). Coupling Models of Different Complexity for the Simulation of CO2 Storage in Deep Saline Aquifers (Bd. 218) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2013/8141/
    3. de Boer, C. (2012). Transport of nano sized zero valent iron colloids during injection into the subsurface (Bd. 215) [Promotionsschrift, Universität Stuttgart, Institut für Wasser- Umweltsystemmodellierung]. http://dx.doi.org/10.18419/opus-486

  12. 2011

    1. Kuhlmann, A. (2011). Influence of soil structure and root water uptake on flow in the unsaturated zone (Bd. 209) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2012/7214/

  13. 2010

    1. Dogan, M. O. (2010). Coupling of porous media flow with pipe flow (Bd. 199) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2011/5942/
    2. Niessner, J. (2010). The Role of Interfacial Areas in Two-Phase Flow in Porous Media -- bridging scales and coupling models [Habilitationsschrift, Universität Stuttgart, Institut für Wasserbau]. In Universität Stuttgart, Stuttgart. https://elib.uni-stuttgart.de/opus/volltexte/2011/6305/
    3. Fritz, J. (2010). A decoupled model for compositional non-isothermal multiphase flow in porous media and multiphysics approaches for two-phase flow (Bd. 192) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung]. https://elib.uni-stuttgart.de/opus/volltexte/2010/5683
    4. Vasin, M. (2010). Influence of the soil structure and property contrast on flow and transport in the unsaturated zone (Bd. 186) [Promotionsschrift, ,]. https://elib.uni-stuttgart.de/opus/volltexte/2010/5169/
    5. Cao, Y. (2010). Robust numerical algorithms based on corrected operator splitting for two-phase flow in porous media [Promotionsschrift, Universität Stuttgart, Universität Stuttgart]. https://www.shaker.de/de/content/catalogue/index.asp?lang=de&ID=8&ISBN=978-3-8322-9237-9

  14. 2009

    1. Kopp, A. (2009). Evaluation of CO2 injection processes in geological formations for site screening (Bd. 182) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. http://elib.uni-stuttgart.de/opus/volltexte/2009/4518/pdf/Dissertation_AndreasKopp.pdf
    2. Ebigbo, A. (2009). Modelling of biofilm growth and its influence on CO2 and water (two-phase) flow in porous media (Bd. 183) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. http://elib.uni-stuttgart.de/opus/volltexte/2009/4489/pdf/Ebigbo_DISS_OPUS.pdf

  15. 2008

    1. Class, H. (2008). Models for non-isothermal compositional gas-liquid flow and transport in porous media [Habilitationsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2009/3847/pdf/class_habil_version1.1.pdf
    2. Assteerawatt, A. (2008). Flow and Transport Modelling of Fractured Aquifers based on a Geostatistical Approach (Bd. 176) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2008/3639/
    3. Freiboth, S. (2008). A phenomenological model for the numerical simulation of multiphase multicomponent processes considering structural alternations of porous media (Bd. 184) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2009/4610/pdf/Dissertation_Freiboth_Sandra.pdf
    4. Papafotiou, A. (2008). Numerical Investigations on the Role of Hysteresis in Heterogeneous Two-Phase Flow Systems (Bd. 171) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2008/3567/

  16. 2007

    1. Ochs, S. O. (2007). Steam injection into saturated porous media - process analysis including experimental and numerical investigations - (Bd. 159) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2007/2971/
    2. Bielinski, A. (2007). Numerical Simulation of CO2 Sequestration in Geological Formations (Bd. 155) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2007/2953/

  17. 2006

    1. Breiting, T. (2006). Techniken und Methoden der Hydroinformatik - Modellierung von komplexen Hydrosystemen im Untergrund (Bd. 144) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2006/2646/pdf/PROMO_PDF.pdf
    2. Flemisch, B. (2006). Non-matching triangulations of curvilinear interfaces applied to electro-mechanics and elasto-acoustics [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/flemisch_thesis.pdf
    3. Niessner, J. (2006). Multi-Scale Modeling of Multi-Phase - Multi-Component Processesin Heterogeneous Porous Media (Bd. 151) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2006/2769/
    4. Manthey, S. (2006). Two-phase flow processes with dynamic effects in porous media - parameter estimation and simulation (Bd. 157) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2007/2951/

  18. 2005

    1. Jose Chackiath, S. (2005). Experimental Investigations on Longitudinal Dispersive Mixing in Heterogeneous Aquifers (Bd. 136) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.
    2. Nowak, W. (2005). Geostatistical Methods for the Identification of Flow and Transport Parameters in the Subsurface (Bd. 134) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2005/2275
    3. Jabir, A. K. (2005). Finite Volume Models for Multiphase Multicomponent Flow through Porous Media (Bd. 132) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.
    4. Rahman, A. Md. (2005). Experimental Investigations on Transverse Dispersive Mixing in Heterogeneous Porous Media (Bd. 140) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2005/2284
    5. Süß, M. (2005). Analysis of the influence of structures and boundaries on flow and transport processes in fractured porous media (Bd. 135) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2005/2229
    6. Kobayashi, K. (2005). Optimization Methods for Multiphase Systems in the Subsurface - Application to Methane Migration in Coal Mining Areas (Bd. 139) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2005/2297

  19. 2004

    1. Jakobs, H. (2004). Simulation nicht-isothermer Gas-Wasser-Prozesse in komplexen Kluft-Matrix-Systemen (Bd. 128) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.

  20. 2003

    1. Neunhäuserer, L. (2003). Diskretisierungsansätze zur Modellierung von Strömungs- und Transportprozessen in geklüftet-porösen Medien (Bd. 119) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2003/1477/
    2. Appt, J. (2003). Analysis of Basin-Scale Internal Waves in Upper Lake Constance (Bd. 123) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.
    3. Paul, M. (2003). Simulation of Two-Phase Flow Processes in Heterogeneous Porous Media with Adaptive Methods (Bd. 120) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2005/2435/pdf/promo_paul.pdf
    4. Hinkelmann, R. (2003). Efficient Numerical Methods and Information-Processing Techniques in Environment Water (Bd. 117) [Habilitationsschrift]. Universität Stuttgart, Institut für Wasserbau.

  21. 2002

    1. Silberhorn-Hemminger, A. (2002). Modellierung von Kluftaquifersystemen: Geostatistische Analyse und deterministisch-stochastische Kluftgenerierung (Bd. 114) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2003/1278/

  22. 2001

    1. Lang, S. (2001). Parallele numerische Simulation instationärer Probleme mit adaptiven Methoden auf unstrukturierten Gittern (Bd. 110) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.
    2. Class, H. (2001). Theorie und numerische Modellierung nichtisothermer Mehrphasenprozesse in NAPL-kontaminierten porösen Medien (Bd. 105) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2005/2436/pdf/promo_holle.pdf

  23. 2000

    1. Braun, C. (2000). Ein Upscaling-Verfahren für Mehrphasenströmungen in porösen Medien (Bd. 103) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.
    2. Huber, R. U. (2000). Compositional Multiphase Flow and Transport in Heterogeneous Porous Media (Bd. 102) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.

  24. 1999

    1. Sheta, H. (1999). Simulation von Mehrphasenvorgängen in porösen Medien unter Einbeziehung von Hystereseeffekten (Bd. 100) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://elib.uni-stuttgart.de/opus/volltexte/2005/2437/pdf/promo_sheta.pdf

  25. 1998

    1. Betz, C. (1998). Wasserdampfdestillation von Schadstoffen im porösen Medium: Entwicklung einer thermischen In-situ-Sanierungstechnologie (Bd. 97) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.

  26. 1997

    1. Cirpka, O. A. (1997). Numerische Methoden zur Simulation des reaktiven Mehrkomponententransports im Grundwasser (Bd. 95) [Promotionsschrift, Universität Stuttgart, Institut für Wasserbau]. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/095_Cirpka_Olaf_Diss.pdf
    2. Emmert, M. (1997). Numerische Modellierung nichtisothermer Gas-Wasser Systeme in porösen Medien (Bd. 92) [Promotionsschrift]. Universität Stuttgart, Institut für Wasserbau.
    3. Helmig, R. (1997). Gekoppelte Strömungs- und Transportprozesse im Untergrund: Ein Beitrag zur Hydrosystemmodellierung (Bd. 91) [Habilitationsschrift]. Universität Stuttgart, Institut für Wasserbau.

wissenschaftliche Publikationen

  1. 2023

    1. Boon, W. M., Gläser, D., Helmig, R., & Yotov, I. (2023). Flux-mortar mixed finite element methods with multipoint flux approximation. Computer Methods in Applied Mechanics and Engineering, 405, 115870. https://doi.org/10.1016/j.cma.2022.115870
    2. Class, H., Keim, L., Schirmer, L., Strauch, B., Wendel, K., & Zimmer, M. (2023). Seasonal Dynamics of Gaseous CO2 Concentrations in a Karst Cave Correspond with Aqueous Concentrations in a Stagnant Water Column. Geosciences, 13, 51. https://doi.org/103390/geosciences13020051
    3. Gedam, S., Pallam, H., Kambhammettu, B. V. N. P., Anupoju, V., & Regonda, S. K. (2023). Investigating the Accuracies in Short-Term Weather Forecasts and Its Impact on Irrigation Practices. Journal of Water Resources Planning and Management, 149(2), 04022079. https://doi.org/10.1061/JWRMD5.WRENG-5644
    4. Ackermann, S., Fest-Santini, S., Veyskarami, M., Helmig, R., & Santini, M. (2023). Experimental validation of a coupling concept for drop formation and growth onto porous materials by high-resolution X-ray imaging technique. International Journal of Multiphase Flow, 160. https://doi.org/10.1016/j.ijmultiphaseflow.2022.104371

  2. 2022

    1. Lunowa, S. B., Mascini, A., Bringedal, C., Bultreys, T., Cnudde, V., & Pop, I. S. (2022). Dynamic Effects during the Capillary Rise of Fluids in Cylindrical Tubes. Langmuir, 38(5), 1680–1688. https://doi.org/10.1021/acs.langmuir.1c02680
    2. Ghosh, T., Gujjala, Y. K., Deb, D., & Raja Sekhar, G. P. (2022). Numerical investigation of spontaneous imbibition in an anisotropic reservoir. Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 8(3), 100. https://doi.org/10.1007/s40948-022-00411-4
    3. Tsinober, A., Rosenzweig, R., Class, H., Helmig, R., & Shavit, U. (2022). The Role of Mixed Convection and Hydrodynamic Dispersion During CO2 Dissolution in Saline Aquifers: A Numerical Study. Water Resources Research, 58(3), e2021WR030494. https://doi.org/10.1029/2021WR030494
    4. Bringedal, C., Schollenberger, T., Pieters, G. J. M., van Duijn, C. J., & Helmig, R. (2022). Evaporation-Driven Density Instabilities in Saturated Porous Media. Transport in Porous Media, 143(2), 297--341. https://doi.org/10.1007/s11242-022-01772-w
    5. Gläser, D., Schneider, M., Flemisch, B., & Helmig, R. (2022). Comparison of cell- and vertex-centered finite-volume schemes for flow in fractured porous media. Journal of Computational Physics, 448, 110715. https://doi.org/10.1016/j.jcp.2021.110715
    6. Koch, T., Wu, H., & Schneider, M. (2022). Nonlinear mixed-dimension model for embedded tubular networks with application to root water uptake. Journal of Computational Physics, 450, 110823. https://doi.org/10.1016/j.jcp.2021.110823
    7. Ahmadi, N., Muniruzzaman, M., Sprocati, R., Heck, K., Mosthaf, K., & Rolle, M. (2022). Coupling soil/atmosphere interactions and geochemical processes: A multiphase and multicomponent reactive transport approach. Advances in Water Resources, 169, 104303. https://doi.org/10.1016/j.advwatres.2022.104303
    8. Hommel, J., Gehring, L., Weinhardt, F., Ruf, M., & Steeb, H. (2022). Effects of Enzymatically Induced Carbonate Precipitation on Capillary Pressure-Saturation Relations. Minerals, 12(10), Article 10. https://doi.org/10.3390/min12101186
    9. Michalkowski, C., Veyskarami, M., Bringedal, C., Helmig, R., & Schleper, V. (2022). Two-phase Flow Dynamics at the Interface Between GDL and Gas Distributor Channel Using a Pore-Network Model. Transport in Porous Media, 144(2), 429--458. https://doi.org/10.1007/s11242-022-01813-4
    10. Weinhardt, F., Deng, J., Hommel, J., Vahid Dastjerdi, S., Gerlach, R., Steeb, H., & Class, H. (2022). Spatiotemporal Distribution of Precipitates and Mineral Phase Transition During Biomineralization Affect Porosity–Permeability Relationships. Transport in Porous Media, 143(2), 527--549. https://doi.org/10.1007/s11242-022-01782-8
    11. Winter, R., Valsamidou, A., Class, H., & Flemisch, B. (2022). A Study on Darcy versus Forchheimer Models for Flow through Heterogeneous Landfills including Macropores. Water, 14(4), Article 4. https://doi.org/10.3390/w14040546
    12. Kelm, M., Gärttner, S., Bringedal, C., Flemisch, B., Knabner, P., & Ray, N. (2022). Comparison study of phase-field and level-set method for three-phase systems including two minerals. Computational Geosciences, 26(3), 545--570. https://doi.org/10.1007/s10596-022-10142-w
    13. Scholz, L., & Bringedal, C. (2022). A Three-Dimensional Homogenization Approach for Effective Heat Transport in Thin Porous Media. Transport in Porous Media, 141(3), 737–769. https://doi.org/10.1007/s11242-022-01746-y

  3. 2021

    1. Wang, W. (王文康), Yang, G. (杨光), Evrim, C., Terzis, A., Helmig, R., & Chu, X. (初旭). (2021). An assessment of turbulence transportation near regular and random permeable interfaces. Physics of Fluids, 33(11), 115103. https://doi.org/10.1063/5.0069311
    2. Seitz, G., Mohammadi, F., & Class, H. (2021). Thermochemical Heat Storage in a Lab-Scale Indirectly Operated CaO/Ca(OH)2 Reactor - Numerical Modeling and Model Validation through Inverse Parameter Estimation. Applied Sciences, 11(2), 682. https://doi.org/10.3390/app11020682
    3. Schneider, J., Groh, J., Pütz, T., Helmig, R., Rothfuss, Y., Vereecken, H., & Vanderborght, J. (2021). Prediction of soil evaporation measured with weighable lysimeters using the FAO Penman–Monteith method in combination with Richards’ equation. Vadose Zone Journal, 20(1), e20102. https://doi.org/10.1002/vzj2.20102
    4. Wang, W., Chu, X., Lozano-Durán, A., Helmig, R., & Weigand, B. (2021). Information transfer between turbulent boundary layers and porous media. Journal of Fluid Mechanics, 920, A21. https://doi.org/10.1017/jfm.2021.445
    5. Lunowa, S. B., Bringedal, C., & Pop, I. S. (2021). On an averaged model for immiscible two-phase flow with surface tension and dynamic contact angle in a thin strip. Studies in Applied Mathematics, 147(1), 84–126. https://doi.org/10.1111/sapm.12376
    6. Anzt, H., Bach, F., Druskat, S., Löffler, F., Loewe, A., Renard, B., Seemann, G., Struck, A., Achhammer, E., Aggarwal, P., Appel, F., Bader, M., Brusch, L., Busse, C., Chourdakis, G., Dabrowski, P., Ebert, P., Flemisch, B., Friedl, S., … Weeber, R. (2021). An environment for sustainable research software in Germany and beyond: current state, open challenges, and call for action version 2; peer review: 2 approved. F1000Research, 9(295), Article 295. https://doi.org/10.12688/f1000research.23224.2
    7. Koch, T., Weishaupt, K., Müller, J., Weigand, B., & Helmig, R. (2021). A (Dual) Network Model for Heat Transfer in Porous Media. Transport in Porous Media, 140(1), 107--141. https://doi.org/10.1007/s11242-021-01602-5
    8. Kurgyis, K., Hommel, J., Flemisch, B., Helmig, R., & Ott, H. (2021). Explicit continuum scale modeling of low-salinity mechanisms. Journal of Petroleum Science and Engineering, 199, 108336. https://doi.org/10.1016/j.petrol.2020.108336
    9. Ahmadi, N., Heck, K., Rolle, M., Helmig, R., & Mosthaf, K. (2021). On multicomponent gas diffusion and coupling concepts for porous media and free flow: a benchmark study. Computational Geosciences, 25(5), 1493--1507. https://doi.org/10.1007/s10596-021-10057-y
    10. von Wolff, L., Weinhardt, F., Class, H., Hommel, J., & Rohde, C. (2021). Investigation of Crystal Growth in Enzymatically Induced Calcite Precipitation by Micro-Fluidic Experimental Methods and Comparison with Mathematical Modeling. Transport in Porous Media, 137(2), Article 2. https://doi.org/10.1007/s11242-021-01560-y
    11. Koch, T., Gläser, D., Weishaupt, K., Ackermann, S., Beck, M., Becker, B., Burbulla, S., Class, H., Coltman, E., Emmert, S., Fetzer, T., Grüninger, C., Heck, K., Hommel, J., Kurz, T., Lipp, M., Mohammadi, F., Scherrer, S., Schneider, M., … Flemisch, B. (2021). DuMux 3 – an open-source simulator for solving flow and transport problems in porous media with a focus on model coupling. Computers & Mathematics with Applications. https://doi.org/10.1016/j.camwa.2020.02.012
    12. Berre, I., Boon, W. M., Flemisch, B., Fumagalli, A., Gläser, D., Keilegavlen, E., Scotti, A., Stefansson, I., Tatomir, A., Brenner, K., Burbulla, S., Devloo, P., Duran, O., Favino, M., Hennicker, J., Lee, I.-H., Lipnikov, K., Masson, R., Mosthaf, K., … Zulian, P. (2021). Verification benchmarks for single-phase flow in three-dimensional fractured porous media. Advances in Water Resources, 147, 103759. https://doi.org/10.1016/j.advwatres.2020.103759
    13. Ackermann, S., Bringedal, C., & Helmig, R. (2021). Multi-scale three-domain approach for coupling free flow and flow in porous media including droplet-related interface processes. Journal of Computational Physics, 429, 109993. https://doi.org/10.1016/j.jcp.2020.109993
    14. Wagner, A., Eggenweiler, E., Weinhardt, F., Trivedi, Z., Krach, D., Lohrmann, C., Jain, K., Karadimitriou, N., Bringedal, C., Voland, P., Holm, C., Class, H., Steeb, H., & Rybak, I. (2021). Permeability Estimation of Regular Porous Structures: A Benchmark for Comparison of Methods. Transport in Porous Media, 138(1), 1–23. https://doi.org/10.1007/s11242-021-01586-2
    15. Chu, X., Wang, W., Yang, G., Terzis, A., Helmig, R., & Weigand, B. (2021). Transport of Turbulence Across Permeable Interface in a Turbulent Channel Flow: Interface-Resolved Direct Numerical Simulation. Transport in Porous Media, 136(1), 165--189. https://doi.org/10.1007/s11242-020-01506-w
    16. Bastidas Olivares, M., Bringedal, C., & Pop, I. S. (2021). A two-scale iterative scheme for a phase-field model for precipitation and dissolution in porous media. Applied Mathematics and Computation, 396, 125933. https://doi.org/10.1016/j.amc.2020.125933
    17. Scheurer, S., Schäfer Rodrigues Silva, A., Mohammadi, F., Hommel, J., Oladyshkin, S., Flemisch, B., & Nowak, W. (2021). Surrogate-based Bayesian comparison of computationally expensive models: application to microbially induced calcite precipitation. Computational Geosciences. https://doi.org/10.1007/s10596-021-10076-9
    18. Bastidas, M., Bringedal, C., Pop, I. S., & Radu, F. A. (2021). Numerical homogenization of non-linear parabolic problems on adaptive meshes. Journal of Computational Physics, 425, 109903. https://doi.org/10.1016/j.jcp.2020.109903
    19. Weinhardt, F., Class, H., Dastjerdi, S. V., Karadimitriou, N., Lee, D., & Steeb, H. (2021). Experimental Methods and Imaging for Enzymatically Induced Calcite Precipitation in a microfluidic cell. Water Resources Research, 57, e2020WR029361. https://doi.org/doi.org/10.1029/2020WR029361
    20. Weishaupt, K., Koch, T., & Helmig, R. (2021). A fully implicit coupled pore-network/free-flow model for the pore-scale simulation of drying processes. Drying Technology, 0(0), 1--22. https://doi.org/10.1080/07373937.2021.1955706
    21. Gao, B., Coltman, E., Farnsworth, J., Helmig, R., & Smits, K. M. (2021). Determination of Vapor and Momentum Roughness Lengths Above an Undulating Soil Surface Based on PIV-Measured Velocity Profiles. Water Resources Research, 57(7), e2021WR029578. https://doi.org/10.1029/2021WR029578
    22. Class, H., Bürkle, P., Sauerborn, T., Trötschler, O., Strauch, B., & Zimmer, M. (2021). On the Role of Density-Driven Dissolution of CO2 in Phreatic Karst Systems. Water Resources Research, 57(12), e2021WR030912. https://doi.org/10.1029/2021WR030912

  4. 2020

    1. Emmert, S., Davis, K., Gerlach, R., & Class, H. (2020). The Role of Retardation, Attachment and Detachment Processes during Microbial Coal-Bed Methane Production after Organic Amendment. Water, 12(11), Article 11. https://doi.org/10.3390/w12113008
    2. Koch, T., Flemisch, B., Helmig, R., Wiest, R., & Obrist, D. (2020). A multi-scale sub-voxel perfusion model to estimate diffusive capillary wall conductivity in multiple sclerosis lesions from perfusion MRI data. International Journal for Numerical Methods in Biomedical Engineering, 36(2), e3298. https://doi.org/10.1002/cnm.3298
    3. Schneider, M., Flemisch, B., Frey, S., Hermann, S., Iglezakis, D., Ruf, M., Schembera, B., Seeland, A., & Steeb, H. (2020). Datenmanagement im SFB 1313. Bausteine Forschungsdatenmanagement, 3(1), 28–38. https://doi.org/10.17192/bfdm.2020.1.8085
    4. Weishaupt, K., Terzis, A., Zarikos, I., Yang, G., Flemisch, B., de Winter, D. A. M., & Helmig, R. (2020). A Hybrid-Dimensional Coupled Pore-Network/Free-Flow Model Including Pore-Scale Slip and Its Application to a Micromodel Experiment. Transport in Porous Media, 135(1), 243--270. https://doi.org/10.1007/s11242-020-01477-y
    5. Ghosh, T., Bringedal, C., Helmig, R., & Sekhar, G. P. R. (2020). Upscaled equations for two-phase flow in highly heterogeneous porous media: Varying permeability and porosity. Advances in Water Resources, 145, 103716. https://doi.org/10.1016/j.advwatres.2020.103716
    6. Shokri-Kuehni, S. M. S., Raaijmakers, B., Kurz, T., Or, D., Helmig, R., & Shokri, N. (2020). Water Table Depth and Soil Salinization: From Pore-Scale Processes to Field-Scale Responses. Water Resources Research, 56(2), e2019WR026707. https://doi.org/10.1029/2019WR026707
    7. Bringedal, C., von Wolff, L., & Pop, I. S. (2020). Phase Field Modeling of Precipitation and Dissolution Processes in Porous Media: Upscaling and Numerical Experiments. Multiscale Modeling & Simulation, 18(2), 1076--1112. https://doi.org/10.1137/19M1239003
    8. Sharmin, S., Bringedal, C., & Pop, I. S. (2020). On upscaling pore-scale models for two-phase flow with evolving interfaces. Advances in Water Resources, 142, 103646. https://doi.org/10.1016/j.advwatres.2020.103646
    9. Coltman, E., Lipp, M., Vescovini, A., & Helmig, R. (2020). Obstacles, Interfacial Forms, and Turbulence: A Numerical Analysis of Soil-Water Evaporation Across Different Interfaces. Transport in porous media, 134(2), 275--301. https://doi.org/10.1007/s11242-020-01445-6
    10. Emmert, S., Class, H., Davis, K. J., & Gerlach, R. (2020). Importance of specific substrate utilization by microbes in microbially enhanced coal-bed methane production: A modelling study. International Journal of Coal Geology, 229, 103567. https://doi.org/10.1016/j.coal.2020.103567
    11. Hommel, J., Akyel, A., Frieling, Z., Phillips, A. J., Gerlach, R., Cunningham, A. B., & Class, H. (2020). A Numerical Model for Enzymatically Induced Calcium Carbonate Precipitation. Applied Sciences, 10(13), 4538. https://doi.org/10.3390/app10134538
    12. Heck, K., Coltman, E., Schneider, J., & Helmig, R. (2020). Influence of Radiation on Evaporation Rates: A Numerical Analysis. Water Resources Research, 56(10), e2020WR027332. https://doi.org/10.1029/2020WR027332
    13. Agélas, L., Schneider, M., Enchéry, G., & Flemisch, B. (2020). Convergence of nonlinear finite volume schemes for two-phase porous media flow on general meshes. IMA Journal of Numerical Analysis. https://doi.org/10.1093/imanum/draa064
    14. Beck, M., Rinaldi, A. P., Flemisch, B., & Class, H. (2020). Accuracy of fully coupled and sequential approaches for modeling hydro- and geomechanical processes. Computational Geosciences, 24(4), 1707--1723. https://doi.org/10.1007/s10596-020-09987-w
    15. de Winter, M., Weishaupt, K., Scheller, S., Frey, S., Raoof, A., Hassanizadeh, M., & Helmig, R. (2020). The Complexity of Porous Media Flow Characterized in a Microfluidic Model Based on Confocal Laser Scanning Microscopy and Micro-PIV. Transport in Porous Media. https://doi.org/10.1007/s11242-020-01515-9
    16. Class, H., Weishaupt, K., & Trötschler, O. (2020). Experimental and Simulation Study on Validating a Numerical Model for CO2 Density-Driven Dissolution in Water. Water, 12(3), 738. https://doi.org/10.3390/w12030738
    17. Koch, T., Schneider, M., Helmig, R., & Jenny, P. (2020). Modeling tissue perfusion in terms of 1d-3d embedded mixed-dimension coupled problems with distributed sources. Journal of Computational Physics, 410, 109370. https://doi.org/10.1016/j.jcp.2020.109370
    18. Bahlmann, L. M., Smits, K. M., Heck, K., Coltman, E., Helmig, R., & Neuweiler, I. (2020). Gas Component Transport Across the Soil-Atmosphere Interface for Gases of Different Density: Experiments and Modeling. Water Resources Research, 56(9), e2020WR027600. https://doi.org/10.1029/2020WR027600
    19. Koch, T., Helmig, R., & Schneider, M. (2020). A new and consistent well model for one-phase flow in anisotropic porous media using a distributed source model. Journal of Computational Physics, 410, 109369. https://doi.org/10.1016/j.jcp.2020.109369
    20. Seitz, G., Helmig, R., & Class, H. (2020). A numerical modeling study on the influence of porosity changes during thermochemical heat storage. Applied Energy, 259, 114152. https://doi.org/10.1016/j.apenergy.2019.114152
    21. Schneider, M., Weishaupt, K., Gläser, D., Boon, W. M., & Helmig, R. (2020). Coupling staggered-grid and MPFA finite volume methods for free flow/porous-medium flow problems. Journal of Computational Physics, 401. https://doi.org/10.1016/j.jcp.2019.109012
    22. Oladyshkin, S., Mohammadi, F., Kroeker, I., & Nowak, W. (2020). Bayesian3 Active Learning for the Gaussian Process Emulator Using Information Theory. Entropy, 22(8), 890. https://doi.org/10.3390/e22080890
    23. Gläser, D., Flemisch, B., Class, H., & Helmig, R. (2020). Frackit: a framework for stochastic fracture network generation and analysis. Journal of Open Source Software, 5. https://doi.org/10.21105/joss.02291

  5. 2019

    1. Beck, M., & Class, H. (2019). Modelling fault reactivation with characteristic stress-drop terms. Advances in Geosciences, 49, 1--7. https://doi.org/10.5194/adgeo-49-1-2019
    2. Zhuang, L., Hassanizadeh, S. M., van Duijn, C. J., Zimmermann, S., Zizina, I., & Helmig, R. (2019). Experimental and Numerical Studies of Saturation Overshoot during Infiltration into a Dry Soil. Vadose Zone Journal, 18(1), 180167. https://doi.org/10.2136/vzj2018.09.0167
    3. Yang, G., Terzis, A., Zarikos, I., Hassanizadeh, S. M., Weigand, B., & Helmig, R. (2019). Internal flow patterns of a droplet pinned to the hydrophobic surfaces of a confined microchannel using micro-PIV and VOF simulations. Chemical Engineering Journal, 370, 444–454. https://doi.org/10.1016/j.cej.2019.03.191
    4. Ghosh, T., Raja Sekhar, G. P., & Deb, D. (2019). Modeling of Co-current Spontaneous Imbibition Oil Recovery from Partially Covered Homogeneous Hydrocarbon Reservoir. Transport in Porous Media, 130(3), Article 3. https://doi.org/10.1007/s11242-019-01349-0
    5. Terzis, A., Zarikos, I., Weishaupt, K., Yang, G., Chu, X., Helmig, R., & Weigand, B. (2019). Microscopic velocity field measurements inside a regular porous medium adjacent to a low Reynolds number channel flow. Physics of Fluids, 31(4), 042001. https://doi.org/10.1063/1.5092169
    6. Bilke, L., Flemisch, B., Kalbacher, T., Kolditz, O., Helmig, R., & Nagel, T. (2019). Development of Open-Source Porous Media Simulators: Principles and Experiences. Transport in Porous Media, 130(1), 337--361. https://doi.org/10.1007/s11242-019-01310-1
    7. Weishaupt, K., Joekar-Niasar, V., & Helmig, R. (2019). An efficient coupling of free flow and porous media flow using the pore-network modeling approach. Journal of Computational Physics: X, 1, 100011. https://doi.org/10.1016/j.jcpx.2019.100011
    8. Mitra, K., Köppl, T., Duijn, H. van, Pop, I. S., & Helmig, R. (2019). Fronts in two-phase porous media flow problems: the effects of hysteresis and dynamic capillarity. Studies in Applied Mathematics, 1906.08134. https://research.tue.nl/en/publications/fronts-in-two-phase-porous-media-flow-problems-the-effects-of-hys
    9. Gläser, D., Flemisch, B., Helmig, R., & Class, H. (2019). A hybrid-dimensional discrete fracture model for non-isothermal two-phase flow in fractured porous media. GEM - International Journal on Geomathematics, 10(1), 5. https://doi.org/10.1007/s13137-019-0116-8
    10. Yang, G., Coltman, E., Weishaupt, K., Terzis, A., Helmig, R., & Weigand, B. (2019). On the Beavers-Joseph interface condition for non-parallel coupled channel flow over a porous structure at high Reynolds numbers. Transport in Porous Media. https://doi.org/10.1007/s11242-019-01255-5
    11. Yang, G., Vaikuntanathan, V., Terzis, A., Cheng, X., Weigand, B., & Helmig, R. (2019). Impact of a linear array of hydrophilic and superhydrophobic spheres on a deep water pool. Colloids and Interfaces. https://doi.org/10.3390/colloids3010029
    12. Vidotto, Ettore., Koch, Timo., Köppl, Tobias., Helmig, Rainer., & Wohlmuth, Barbara. (2019). Hybrid Models for Simulating Blood Flow in Microvascular Networks. Multiscale Modeling & Simulation, 17(3), 1076--1102. https://doi.org/10.1137/18M1228712
    13. Cunningham, A. B., Class, H., Ebigbo, A., Gerlach, R., Phillips, A. J., & Hommel, J. (2019). Field-scale modeling of microbially induced calcite precipitation. Computational Geosciences, 23(2), 399--414. https://doi.org/10.1007/s10596-018-9797-6

  6. 2018

    1. Köppl, T., Santin, G., Haasdonk, B., & Helmig, R. (2018). Numerical modelling of a peripheral arterial stenosis using dimensionally reduced models and machine learning techniques. International Journal for Numerical Methods in Biomedical Engineering. https://doi.org/10.1002/cnm.3095
    2. Schneider, M., Flemisch, B., Helmig, R., Terekhov, K., & Tchelepi, H. (2018). Monotone nonlinear finite-volume method for challenging grids. Computational Geosciences. https://doi.org/10.1007/s10596-017-9710-8
    3. Gao, B., Davarzani, H., Helmig, R., & Smits, K. M. (2018). Experimental and numerical study of evaporation from wavy surfaces by coupling free flow and porous media flow. Water Resources Research. https://doi.org/10.1029/2018WR023423
    4. Becker, B., Guo, B., Bandilla, K., Celia, M. A., Flemisch, B., & Helmig, R. (2018). An adaptive multiphysics model coupling vertical equilibrium and full multidimensions for multiphase flow in porous media. Water Resources Research, 54. https://doi.org/10.1029/2017WR022303
    5. Köppl, T., Vidotto, E., Wohlmuth, B. I., & Zunino, P. (2018). Mathematical modeling, analysis and numerical approximation of second order elliptic problems with inclusions. Mathematical Models and Methods in Applied Sciences, 28(5), Article 5. https://doi.org/10.1142/S0218202518500252
    6. Vidotto, E., Helmig, R., Schneider, M., & Wohlmuth, B. (2018). Streamline method for resolving sharp fronts for complex two-phase flow in porous media. Computational Geosciences, 22(6), 1487--1502. https://doi.org/10.1007/s10596-018-9767-z
    7. Koch, T., Heck, K., Schröder, N., Class, H., & Helmig, R. (2018). A new simulation framework for soil-root interaction, evaporation, root growth, and solute transport. Vadose Zone Journal. https://doi.org/10.2136/vzj2017.12.0210
    8. Schneider, M., Köppl, T., Helmig, R., Steinle, R., & Hilfer, R. (2018). Stable propagation of saturation overshoots for two-phase flow in porous media. Transport in Porous Media, 121(3), Article 3. https://doi.org/10.1007/s11242-017-0977-y
    9. Praditia, T., Helmig, R., & Hajibeygi, H. (2018). Multiscale formulation for coupled flow-heat equations arising from single-phase flow in fractured geothermal reservoirs. Computational Geosciences. https://doi.org/10.1007/s10596-018-9754-4
    10. Koch, T., Gläser, D., Weishaupt, K., Ackermann, S., Beck, M., Becker, B., Burbulla, S., Class, H., Coltman, E., Fetzer, T., Flemisch, B., Grüninger, C., Heck, K., Hommel, J., Kurz, T., Lipp, M., Mohammadi, F., Schneider, M., Seitz, G., … Weinhardt, F. (2018). DuMuX 3.0.0. https://doi.org/10.5281/zenodo.2479595
    11. Hommel, J., Coltman, E., & Class, H. (2018). Porosity-Permeability Relations for Evolving Pore Space: A Review with a Focus on (Bio-)geochemically Altered Porous Media. Transport in Porous Media, 2(124), Article 124. https://doi.org/10.1007/s11242-018-1086-2
    12. Köppl, T., Fedoseyev, M., & Helmig, R. (2018). Simulation of surge reduction systems using dimensionally reduced models. Journal of Hydraulic Engineering. https://doi.org/10.1061/(ASCE)HY.1943-7900.0001553
    13. Mohammadi, F., Kopmann, R., Guthke, A., Oladyshkin, S., & Nowak, W. (2018). Bayesian selection of hydro-morphodynamic models under computational time constraints. Advances in Water Resources, 117, 53–64. https://doi.org/10.1016/j.advwatres.2018.05.007
    14. Schneider, M., Gläser, D., Flemisch, B., & Helmig, R. (2018). Comparison of finite-volume schemes for diffusion problems. Oil & Gas Science and Technology – Revue d’IFP Energies nouvelles, 73. https://ogst.ifpenergiesnouvelles.fr/articles/ogst/pdf/2018/01/ogst180050.pdf

  7. 2017

    1. Yang, G., Weigand, B., Terzis, A., Weishaupt, K., & Helmig, R. (2017). Numerical simulation of turbulent flow and heat transfer in a three-dimensional channel coupled with flow through porous structures. Transport in Porous Media, 120. https://doi.org/10.1007/s11242-017-0995-9
    2. Mejri, E., Bouhlila, R., & Helmig, R. (2017). Heterogeneity effects on evaporation-induced halite and gypsum co-precipitation in porous media. Transport in Porous Media. https://doi.org/10.1007/s111242-017-0846-8
    3. Schneider, M., Agélas, L., Enchery, G., & Flemisch, B. (2017). Convergence of nonlinear finite volume schemes for heterogeneous anisotropic diffusion on general meshes. 351. https://doi.org/10.1016/j.jcp.2017.09.003
    4. Jabbari, M., Shojaee Nasirabadi, P., Jambhekar, V. A., Hattel, J. H., & Helmig, R. (2017). Drying of a tape-cast layer: Numerical investigation of influencing parameters. International Journal of Heat and Mass Transfer, 108. https://doi.org/10.1016/j.ijheatmasstransfer.2017.01.074
    5. Fetzer, T., Vanderborght, J., Mosthaf, K., Smits, K. M., & Helmig, R. (2017). Heat and water transport in soils and across the soil-atmosphere interface: 2. Numerical analysis. Water Resources Research, 53(2), Article 2. https://doi.org/10.1002/2016WR019983
    6. Gläser, D., Helmig, R., Flemisch, B., & Class, H. (2017). A discrete fracture model for two-phase flow in fractured porous media. Advances in Water Resources, 110. https://doi.org/10.1016/j.advwatres.2017.10.031
    7. Sander, O., Koch, T., Schröder, N., & Flemisch, B. (2017). The Dune FoamGrid implementation for surface and network grids. Archive of Numerical Software, 5. https://dx.doi.org/10.11588/ans.2017.1.28490
    8. Schneider, M., Flemisch, B., & Helmig, R. (2017). Monotone nonlinear finite-volume method for nonisothermal two-phase two-component flow in porous media. International Journal for Numerical Methods in Fluids, 84(6), Article 6. https://doi.org/10.1002/fld.4352
    9. Trautz, A., Illangasekare, T., Rodriguez-Iturbe, I., Heck, K., & Helmig, R. (2017). Development of an experimental approach to study coupled soil-plant-atmosphere processes using plant analogs. Water Resources Research, 53.
    10. Terzis, A., Roumeli, E., Weishaupt, K., Brack, S., Aslannejad, H., Groß, J., Hassanizadeh, S. M., Helmig, R., & Weigand, B. (2017). Heat release at the wetting front during capillary filling of cellulosic micro-substrates. Journal of Colloid and Interface Science. https://doi.org/10.1016/j.jcis.2017.06.027
    11. Gupta, S., Deusner, C., Haeckel, M., Helmig, R., & Wohlmuth, B. I. (2017). Testing a thermo-chemo-hydro-geomechanical model for gas hydrate bearing sediments using triaxial compression lab experiments. https://doi.org/10.1002/2017GC006901
    12. Vanderborght, J., Fetzer, T., Mosthaf, K., Smits, K. M., & Helmig, R. (2017). Heat and water transport in soils and across the soil-atmosphere interface: 1. Theory and different model concepts. Water Resources Research, 53(2), Article 2. https://doi.org/10.1002/2016WR019982
    13. Kempf, D., & Koch, T. (2017). System testing in scientific numerical software frameworks using the example of DUNE. Archive of Numerical Software, 5. https://dx.doi.org/10.11588/ans.2017.1.27447
    14. Becker, B., Guo, B., Bandilla, K., Celia, M. A., Flemisch, B., & Helmig, R. (2017). A pseudo-vertical equilibrium model for slow gravity drainage dynamics. Water Resources Research, 53. https://doi.org/10.1002/2017WR021644
    15. Neuweiler, I., & Helmig, R. (2017). Debates - Hypothesis testing in hydrology: a subsurface perspective. Water Resources Research, 53. https://doi.org/1002/2016WR020047

  8. 2016

    1. Jabbari, M., Jambhekar, V. A., Hattel, J. H., & Helmig, R. (2016). Drying of a tape-cast layer: Numerical modelling of the evaporation process in a graded/layered material. International Journal of Heat and Mass Transfer, 103. https://doi.org/10.1016/j.ijheatmasstransfer.2016.08.073
    2. Kissinger, A., Noack, V., Knopf, S., Konrad, W., Scheer, D., & Class, H. (2016). Regional-scale brine migration along vertical pathways due to CO2 injection - Part 2: a simulated case study in the North German Basin. Hydrology and Earth System Sciences (HESS).
    3. Beck, M., Seitz, G., & Class, H. (2016). Volume-Based Modelling of Fault Reactivation in Porous Media Using a Visco-Elastic Proxy Model. Transport in Porous Media.
    4. Baber, K., Flemisch, B., & Helmig, R. (2016). Modelling drop dynamics at the interface between free and porous-medium flow using the mortar method. International Journal of Heat and Mass Transfer. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2014/SimTech_Preprint_Baber2014.pdf
    5. Drzisga, D., Köppl, T., Pohl, U., Helmig, R., & Wohlmuth, B. I. (2016). Numerical modeling of compensation mechanisms for peripheral arterial stenoses. Computers in Biology and Medicine, 70, Article 70.
    6. Kissinger, A., Noack, V., Knopf, S., Konrad, W., Scheer, D., & Class, H. (2016). Brine migration along vertical pathways due to CO2 injection - a simulated case study in the North German Basin with stakeholder involvement. https://doi.org/10.5194/hess-2016-281
    7. Gupta, S., Wohlmuth, B. I., & Helmig, R. (2016). Multi-rate time stepping schemes for hydro-geomechanical model for subsurface methane hydrate reservoirs. Advances in Water Resources, 91. https://doi.org/10.1016/j.advwatres.2016.02.013
    8. Schmid, K. S., Alyafei, N., Geiger, S., & Blunt, M. (2016). Analytical Solutions for Spontaneous Imbibition: Fractional-Flow Theory and Experimental Analysis. SPE Journal. https://doi.org/10.2118/184393-PA
    9. Blatt, M., Burchardt, A., Dedner, A., Engwer, C., Fahlke, J., Flemisch, B., Gersbacher, C., Gräser, C., Gruber, F., Grüninger, C., Kempf, D., Klöfkorn, R., Malkmus, T., Müthing, S., Nolte, M., Piatkowski, M., & Sander, O. (2016). The Distributed and Unified Numerics Environment, Version 2.4. Archive of Numerical Software, 4(100), Article 100. https://doi.org/10.11588/ans.2016.100.26526
    10. Fattahi, E., Waluga, C., Wohlmuth, B. I., Rüde, U., Manhard, M., & Helmig, R. (2016). Lattice Boltzmann methods in porous media simulations: laminar to turbulent flow. Computers and fluids, 140.
    11. Weishaupt, K., Bordenave, A., Atteia, O., & Class, H. (2016). Numerical Investigation on the Benefits of Preheating for an Increased Thermal Radius of Influence During Steam Injection in Saturated Soil. Transport in Porous Media. https://doi.org/10.1007/s11242-016-0624-z
    12. Jambhekar, V. A., Mejri, E., Schröder, N., Helmig, R., & Shokri, N. (2016). Kinetic Approach to Model Reactive Transport and Mixed Salt Precipitation in a Coupled Free-Flow–Porous-Media System. Transport in Porous Media. https://doi.org/10.1007/s11242-016-0665-3
    13. Szymanska, P., Tisler, W., Schütz, C., Szymkiewicz, A., Neuweiler, I., & Helmig, R. (2016). Experimental and numerical analysis of air trapping in a porous medium with coarse textured inclusions. Acta Geophysica, 64.
    14. Fraundorf, P., & Lipp, M. (2016). Molar standards & information units in the „new-SI“. https://hal.archives-ouvertes.fr/hal-01381003/file/MolarStandardsAndInformationUnits.pdf
    15. Fetzer, T., Smits, K. M., & Helmig, R. (2016). Effect of Turbulence and Roughness on Coupled Porous-Medium/Free-Flow Exchange Processes. Transport in Porous Media, 114(2), Article 2. https://doi.org/10.1007/s11242-016-0654-6
    16. Lindner, F., Nuske, P., Weishaupt, K., Helmig, R., Mundt, C., & Pfitzner, M. (2016). Transpiration cooling with local thermal nonequilibrium: Model comparison in multiphase flow in porous media. Journal of Porous Media, 19. https://doi.org/10.1615/JPorMedia.v19.i2.30
    17. Hommel, J., Ebigbo, A., Gerlach, R., Cunningham, A. B., Helmig, R., & Class, H. (2016). Finding a balance between accuracy and effort for modeling biomineralization. Energy Procedia, 97. https://doi.org/10.1016/j.egypro.2016.10.028
    18. Gläser, D., Dell’Oca, A., Tatomir, A., Bensabat, J., Class, H., Guadagnini, A., Helmig, R., McDermott, C., Riva, M., & Sauter, M. (2016). An Approach Towards a FEP-based Model for Risk Assessment for Hydraulic Fracturing Operations. Energy Procedia, 97, 387--394. https://doi.org/10.1016/j.egypro.2016.10.030
    19. Scheer, D., Konrad, W., Class, H., Kissinger, A., Knopf, S., & Noack, V. (2016). Regional-scale brine migration along vertical pathways due to CO2 injection - Part 1: the participatory modeling approach. Hydrology and Earth System Sciences (HESS).
    20. Helmig, R., Hassanizadeh, S. M., & Dahle, H. K. (2016). Foreword. NUPUS: Porous media research has got a brand name. Transport in Porous Media, 114. https://doi.org/10.1007/s11242-016-0736-5
    21. Hommel, J., Lauchnor, E., Gerlach, R., Cunningham, A. B., Ebigbo, A., Helmig, R., & Class, H. (2016). Investigating the influence of the initial biomass distribution and injection strategies on biofilm-mediated calcite precipitation in porous media. Transport in Porous Media, 114(2), Article 2. https://doi.org/10.1007/s11242-015-0617-3

  9. 2015

    1. Rybak, I., Magiera, J., Helmig, R., & Rohde, C. (2015). Multirate time integration for coupled saturated/unsaturated porous medium and free flow systems. Computational Geosciences. https://doi.org/10.1007/s10596-015-9469-8
    2. Kleinknecht, S., Class, H., & Braun, J. (2015). Density-driven migration of heavy NAPL vapor in the unsaturated zone. Vadose Zone Journal, 14(8). https://doi.org/10.2136/vzj2014.12.0173
    3. Faigle, B., Elfeel, M. A., Helmig, R., Becker, B., Flemisch, B., & Geiger, S. (2015). Multi-physics modeling of non-isothermal compositional flow on adaptive grids. Computational Methods in Applied Mechanical Engineering, 292. https://doi.org/10.1016/j.cma.2014.11.030
    4. Enzenhöfer, R., Nowak, W., & Binning, P. J. (2015). Stakeholder-Objective Risk Model (STORM): Assessing the risk of multiple contaminant sources in groundwater catchments for pumping well management. Advances in Water Resources, 83. https://doi.org/10.1016/j.advwatres.2015.05.015
    5. Scheer, D., Konrad, W., Class, H., Kissinger, A., Knopf, S., & Noack, V. (2015). Expert involvement in science development: (re-)evaluation of an early screening tool for carbon storage site characterization. International Journal of Greenhouse Gas Control, 37.
    6. Class, H., Mahl, L., Ahmed, W., Norden, B., Kühn, M., & Kempka, T. (2015). Matching Pressure Measurements and Observed CO2 Arrival Times with Static and Dynamic Modelling at the Ketzin Storage site. Energy Procedia, 76.
    7. Kaulmann, S., Flemisch, B., Haasdonk, B., Lie, K.-A., & Ohlberger, M. (2015). The localized reduced basis multiscale method for two-phase flows in porous media. International Journal of Numerical Methods in Engineering, 102. https://onlinelibrary.wiley.com/doi/10.1002/nme.4773/full
    8. Hommel, J., Lauchnor, E., Phillips, A., Gerlach, R., Cunningham, A. B., Helmig, R., Ebigbo, A., & Class, H. (2015). A revised model for microbially induced calcite precipitation: Improvements and new insights based on recent experiments. Water Resources Research, 51(5), Article 5. https://doi.org/10.1002/2014WR016503
    9. Nuske, P., Ronneberger, O., Karadimitriou, N., Helmig, R., & Hassanizadeh, S. M. (2015). Modelling Multi-Phase Flow in a Micro-Model with Local Thermal Non-Equilibrium on the Darcy Scale. International Journal of Heat and Mass Transfer, 88.
    10. Tatomir, A., Schaffer, M., Kissinger, A., Hommel, J., Nuske, P., Licha, T., Helmig, R., & Sauter, M. (2015). Novel approach for modeling kinetic interface-sensitive (KIS) tracers with respect to time-dependent interfacial area change for the optimization of supercritical carbon dioxide injection into deep saline aquifers. International Journal of Greenhouse Gas Control, 33. https://doi.org/10.1016/j.ijggc.2014.11.020
    11. Schwenck, N., Flemisch, B., Helmig, R., & Wohlmuth, B. I. (2015). Dimensionally reduced flow models in fractured porous media: crossings and boundaries. Computational Geosciences, 19(6), Article 6. https://doi.org/10.1007/s10596-015-9536-1
    12. Gerbersdorf, S. U., Cimatoribus, C., Class, H., Engesser, K.-H., Helbich, S., Hollert, H., Lange, C., Kranert, M., Metzger, J. W., Nowak, W., Seiler, T.-B., Steger, K., Steinmetz, H., & Wieprecht, S. (2015). Anthropogenic Trace Compounds (ATCs) in aquatic habitats - Research needs on sources, fate, detection and toxicity to ensure timely elimination strategies and risk management. Environment International, Vol.79.2015. https://doi.org/10.1016/j.envint.2015.03.011

  10. 2014

    1. Kissinger, A., Noack, V., Knopf, S., Scheer, D., Konrad, W., & Class, H. (2014). Characterization of reservoir conditions for CO2 storage using a dimensionless Gravitational Number applied to the North German Basin. Sustainable Energy Technologies and Assessments, 7. https://doi.org/10.1016/j.seta.2014.06.003
    2. Wöhling, T., Schöniger, A., & Nowak, W. (2014). Bayesian model averaging to explore the worth of data for maximum-confidence soil-plant model selection and prediction. Water Resources Research.
    3. Schaedle, P., Hubschwerlen, N., & Class, H. (2014). Optimizing the modeling performance for safety assessments of nuclear waste repositories by approximating two-phase flow and transport by single-phase transport simulations. Nuclear Technology, 187.
    4. Karadimitriou, N., Nuske, P., Kleingeld, P., Hassanizadeh, S. M., & Helmig, R. (2014). Simultaneous thermal and optical imaging of two-phase flow in a micro-model. https://doi.org/10.1039/c4lc00321g
    5. Faigle, B., Helmig, R., Aavatsmark, I., & Flemisch, B. (2014). Efficient multiphysics modelling with adaptive grid-refinement using an MPFA method. Computational Geosciences, 18(5), Article 5. https://doi.org/10.1007/s10596-014-9407-1
    6. Schmid, K. S., Groß, J., & Helmig, R. (2014). Chemical osmosis in two-phase flow and salinity-dependent capillary pressures in rocks with microporosity. Water Resources Research. https://doi.org/10.1002/2013WR013848
    7. Nuske, P., Joekar-Niasar, V., & Helmig, R. (2014). Non-Equilibrium in Multiphase Multicomponent Flow in Porous Media: An Evaporation Example. International Journal of Heat and Mass Transfer. https://doi.org/10.1016/j.ijheatmasstransfer.2014.03.011
    8. Nowak, W., Bode, F., & Loschko, M. (2014). A multi-objective optimization concept for risk-based early-warning monitoring networks in well catchments.
    9. Köppl, T., Schneider, M., Pohl, U., & Wohlmuth, B. I. (2014). The influence of an unilateral carotid artery stenosis on brain oxygenation. Medical Engineering and Physics, 36(7).
    10. Lindner, F., Nuske, P., Helmig, R., Mundt, C., & Pfitzner, M. (2014). Transpiration Cooling with Local Thermal Non-Equilibrium: Model Comparison in Multiphase Flow in Porous Media. Journal of Porous Media.
    11. Maier, C., Schmid, K. S., Ahmed, M., & Geiger, S. (2014). Multi-Rate Mass-Transfer Dual-Porosity Modelling Using the Exact Analytical Solution for Spontaneous Imbibition. Society of Petroleum Engineers. https://doi.org/0.2118/164926-MS
    12. Koch, J., & Nowak, W. (2014). A method for implementing Dirichlet and third-type boundary conditions in PTRW simulations. Water Resources Research, 50(2), Article 2. https://doi.org/10.1002/2013WR013796
    13. Kröker, I., Nowak, W., & Rohde, C. (2014). A stochastically and spatially adaptive parallel scheme for uncertain and non-linear two-phase flow problems. Computational Geosciences.
    14. Szymkiewicz, A., Neuweiler, I., & Helmig, R. (2014). Influence of heterogeneous air entry pressure on large scale unsaturated flow in porous media. Computers in Biology and Medicine, 62. https://doi.org/10.2478/s11600-014-0224-7
    15. Mosthaf, K., Helmig, R., & Or, D. (2014). Modeling and analysis of evaporation processes from porous media on the REV scale. Water Resources Research, 50. https://doi.org/10.1002/2013WR014442
    16. Enzenhöfer, R., Bunk, T., & Nowak, W. (2014). Nine steps to risk-informed wellhead protection and management: A case study. Ground Water, 52. https://doi.org/10.1111/gwat.12161
    17. Huber, K., Vanderborght, J., Javaux, M., Schröder, N., Dodd, I. C., & Vereecken, H. (2014). Modelling the impact of heterogeneous rootzone water distribution on the regulation of transpiration by hormone transport and/or hydraulic pressures. Plant and Soil, 384. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2015/PS_Huber_2014.pdf
    18. Schöniger, A., Wöhling, T., Samaniego, L., & Nowak, W. (2014). Model selection on solid ground: rigorous comparison of nine ways to evaluate Bayesian evidence. Water Resources Research.

  11. 2013

    1. Schmid, K. S., & Geiger, S. (2013). Universal Scaling of Spontaneous Imbibition for Arbitrary Petrophysical Properties: Water-Wet and Mixed-Wet States and Handy’s Conjecture. Journal of Petroleum Science and Engineering, 101. https://doi.org/10.1016/j.petrol.2012.11.015
    2. Helmig, R., Flemisch, B., Wolff, M., Ebigbo, A., & Class, H. (2013). Model coupling for multiphase flow in porous media. Advances in Water Resources, 51. https://doi.org/10.1016/j.advwatres.2012.07.003
    3. Kempka, T., Class, H., Görke, U.-J., Norden, B., Kolditz, O., Kühn, M., Walter, L., Wang, W., & Zehner, B. (2013). A dynamic flow simulation code intercomparison based on the revised static model of the Ketzin pilot site. Energy Procedia, 40.
    4. Schröder, N., Lazarovitch, N., Vanderborght, J., Vereecken, H., & Javaux, M. (2013). Linking transpiration reduction to rhizosphere salinity using a 3D coupled soil-plant model. Plant and Soil, 377. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2015/PS_Schroeder_2013.pdf
    5. Oladyshkin, S., Class, H., & Nowak, W. (2013). Bayesian updating via Bootstrap filtering combined with data-driven polynomial chaos expansions: methodology and application to history matching for carbon dioxide storage in geological formations. Computational Geosciences, 17(4), Article 4. https://doi.org/10.1007/s10596-013-9350-6
    6. Juanes, R., & Class, H. (2013). Special issue on computational methods in geologic CO2 sequestration. Advances in Water Resources, 62. https://doi.org/10.1016/j.advwatres.2013.10.012
    7. Oladyshkin, S., Schröder, P., Class, H., & Nowak, W. (2013). Chaos expansion based Bootstrap filter to calibrate CO2 injection models. Energy Procedia, 40, Article 40. https://doi.org/10.1016/j.egypro.2013.08.046
    8. Leube, P., de Barros, F. P. J., Nowak, W., & Rajagopal, R. (2013). Towards optimal allocation of computer resources: trade-offs between uncertainty quantification, discretization and model reduction. Environmental Modelling & Software, 50. https://doi.org/10.1016/j.envsoft.2013.08.008
    9. Köppl, T., Wohlmuth, B. I., & Helmig, R. (2013). Reduced one-dimensional modelling and numerical simulation for mass transport in fluids. International Journal for Numerical Methods in Fluids, 72. https://doi.org/10.1002/fld.3728
    10. Grathwohl, P., Rügner, H., Wöhling, T., Osenbrück, K., Schwientek, M., Gayler, S., Wollschläger, U., Selle, B., Pause, M., Delfs, J.-O., Grzeschik, M., Weller, U., Ivanov, M., Cirpka, O. A., Maier, A., Kuch, B., Nowak, W., Wulfmeyer, V., Warrach-Sagi, K., … Manthey, S. (2013). Catchments as Reactors: A comprehensive approach for water fluxes and solute turn-over. Environmental Earth Sciences, 69.
    11. Lange, T., Sauter, M., Heitfeld, M., Schetelig, K., Brosig, K., Jahnke, W., Kissinger, A., Helmig, R., Ebigbo, A., & Class, H. (2013). Hydraulic fracturing in unconventional gas reservoirs: risks in the geological system, part 1. Environmental Earth Sciences. https://doi.org/10.1007/s12665-013-2803-3
    12. Kissinger, A., Helmig, R., Ebigbo, A., Class, H., Lange, T., Sauter, M., Heitfeld, M., Klünker, J., & Jahnke, W. (2013). Hydraulic fracturing in unconventional gas reservoirs: risks in the geological system, part 2. Environmental Earth Sciences. https://doi.org/10.1007/s12665-013-2578-6
    13. Walter, L., Binning, P. J., & Class, H. (2013). Predicting salt intrusion into freshwater aquifers resulting from CO2 injection - a study on the influence of conservative assumptions. Advances in Water Resources, 62.
    14. Ashraf, M., Oladyshkin, S., & Nowak, W. (2013). Geological storage of CO2: global sensitivity analysis and risk assessment using arbitrary polynomial chaos expansion. International Journal of Greenhouse Gas Control, 19. https://doi.org/10.1016/j.ijggc.2013.03.023
    15. Wolff, M., Flemisch, B., & Helmig, R. (2013). An adaptive multi-scale approach for modeling two-phase flow in porous media including capillary pressure. Water Resources Research, 49(12), Article 12. https://onlinelibrary.wiley.com/doi/10.1002/2013WR013800/full
    16. Wöhling, T., Geiges, A., Nowak, W., Gayler, S., Högy, P., & Wizemann, H. D. (2013). Towards optimizing experiments for maximum-confidence model selection between different soil-plant models. 19. https://doi.org/10.1016/j.proenv.2013.06.058
    17. Pracht, U. S., Heintze, E., Clauss, C., Hafner, D., Bek, R., Werner, D., Gelhorn, S., Scheffler, M., Dressel, M., Sherman, D., Gorshunov, B., Il’in, K. S., Henrich, D., & Siegel, M. (2013). Electrodynamics of the Superconducting State in Ultra-Thin Films at THz Frequencies. IEEE Transactions on Terahertz Science and Technology, 3(3), 269–280. https://doi.org/10.1109/TTHZ.2013.2255047
    18. Nowak, W., & Litvinenko, A. (2013). Kriging accelerated by orders of magnitude: combining low-rank covariance approximations with FFT-techniques. Mathematical Geosciences, 45(4), Article 4. https://doi.org/10.1007/s11004-013-9453-6
    19. Hommel, J., Cunningham, A. B., Helmig, R., Ebigbo, A., & Class, H. (2013). Numerical Investigation of Microbially Induced Calcite Precipitation as a Leakage Mitigation Technology. Energy Procedia, 40,2013. https://doi.org/10.1016/j.egypro.2013.08.045

  12. 2012

    1. Schröder, N., Javaux, M., Vanderborght, J., Steffen, B., & Vereecken, H. (2012). Effect of Root Water and Solute Uptake on Apparent Soil Dispersivity: A Simulation Study. Vadose Zone Journal, 11. https://doi.org/10.2136/vzj2012.0009
    2. Bauer, S., Class, H., Ebert, M., Feeser, V., Götze, H., Holzheid, A., Kolditz, O., Rosenbaum, S., Rabbel, W., Schäfer, D., & Dahmke, A. (2012). Modeling, parameterization and evaluation of monitoring methods for CO2 storage in deep saline formations: the CO2-MoPa project. Environmental Earth Sciences, 67. https://doi.org/10.1007/s12665-012-1707-y
    3. Schmid, K. S., Geiger, S., & Sorbie, K. S. (2012). Higher Order FE-FV Methods on Unstructured Grids for Transport and Two-Phase Flow with Variable Viscosity in Heterogeneous Porous Media. Journal Of Computational Physics, 241. https://doi.org/10.1016/j.jcp.2012.12.017
    4. Sauter, M., Helmig, R., & Klünker, J. (2012). Risiken im Geologischen System bei der Fracking-Technologie: Abschätzung der Auswirkungen auf Grundwasservorkmmen. Wasser und Abfall, Boden, Altlasten, Umweltschutz, 14.
    5. Geiger, S., Schmid, K. S., & Zaretskiy, Y. (2012). Mathematical analysis and numerical simulation of multi-phase multi-component flow in heterogeneous porous media. Cambridge University Press, 17. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2012/geiger_etal2012_CurrOpinionReview.pdf
    6. de Barros, F. P. J., Dentz, M., Koch, J., & Nowak, W. (2012). Flow topology and scalar mixing in spatially heterogeneous flow fields. Geophysical Research Letters, 39(L08404), Article L08404. https://doi.org/10.1029/2012GL051302
    7. Leube, P., Geiges, A., & Nowak, W. (2012). Bayesian assessment of the expected data impact on prediction confidence in optimal sampling design. Water Resources Research, 48. https://doi.org/10.1029/2010WR010137
    8. Troldborg, M., Nowak, W., Lange, I., Santos, M., Binning, P. J., & Bjerg, P. L. (2012). Application of Bayesian geostatistics for evaluation of mass discharge uncertainty at contaminated sites. Water Resources Research, 48(W09535), Article W09535. https://doi.org/10.1029/2011WR011785
    9. Nordbotten, J. M., Flemisch, B., Gasda, S. E., Nilsen, H. M., Fan, Y., Pickup, G. E., Wiese, B., Celia, M. A., Dahle, H. K., Eigestad, G. T., & Pruess, K. (2012). Uncertainties in practical simulation of CO2 storage. International Journal of Greenhouse Gas Control, 9. https://www.sciencedirect.com/science/article/pii/S1750583612000655
    10. Richter, T., Rudlof, S., Adjibadji, B., Bernlöhr, H., Grüninger, C., Munz, C.-D., Stock, A., Rohde, C., & Helmig, R. (2012). ViPLab - A Virtual Programming Laboratory for Mathematics and Engineering. Interactive Technology and Smart Education, 9(4), Article 4. https://doi.org/10.1108/17415651211284039
    11. Walter, L., Binning, P. J., Oladyshkin, S., Flemisch, B., & Class, H. (2012). Brine migration resulting from CO2 injection into saline aquifers - An approach to risk estimation including various levels of uncertainty. International Journal of Greenhouse Gas Control, 9. https://www.sciencedirect.com/science/article/pii/S1750583612001077
    12. Oladyshkin, S., & Panfilov, M. (2012). Open thermodynamic model for compressible multicomponent two-phase flow in porous media. Journal of Petroleum Science and Engineering, 81. https://doi.org/10.1016/j.petrol.2011.12.001
    13. Oladyshkin, S., & Nowak, W. (2012). Data-driven uncertainty quantification using the arbitrary polynomial chaos expansion. Reliability Engineering & System Safety, 106. https://doi.org/10.1016/j.ress.2012.05.002
    14. Schöniger, A., Nowak, W., & Hendricks Franssen, H.-J. (2012). Parameter estimation by ensemble Kalman filters with transformed data: Approach and application to hydraulic tomography. Water Resources Research, 48(W04502), Article W04502. https://doi.org/10.1029/2011WR010462
    15. Flemisch, B., Kaltenbacher, M., Triebenbacher, S., & Wohlmuth, B. I. (2012). Non-matching grids for a flexible discretization in computational acoustics. 11. https://doi.org/10.4208/cicp.141209.280810s
    16. Oladyshkin, S., de Barros, F. P. J., & Nowak, W. (2012). Global sensitivity analysis: a flexible and efficient framework with an example from stochastic hydrogeology. Advances in Water Resources, 37. https://doi.org/10.1016/j.advwatres.2011.11.001
    17. Schmid, K. S., Geiger, S., & Sorbie, K. S. (2012). Analytical solutions for co- and countercurrent imbibition of sorbing, dispersive solutes in immiscible two-phase flow. Computational Geosciences, 16. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2012/Schmid_etal_AnalyticalSolutionsAdsorbing_COmpGEosc.pdf
    18. Schmid, K. S., & Geiger, S. (2012). Universal Scaling of Spontaneous Imbibition for Water Wet Rocks. Water Resources Research, 48. https://doi.org/10.1029/2011WR011566
    19. Erbertseder, K., Reichold, J., Helmig, R., Jenny, P., & Flemisch, B. (2012). A coupled discrete / continuum model for describing cancer therapeutic transport in the lung. PloS ONE (Public Library of Science Online Journal), 7(3), Article 3. https://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0031966
    20. Stoverud, K. H., Darcis, M., Helmig, R., & Hassanizadeh, S. M. (2012). Modeling concentration distribution and deformation during convection-enhanced drug delivery into brain tissue. Transport in Porous Media, 92(1), Article 1.
    21. Drewes, J., Geist, J., Hegerl, G., Helmig, R., Huber, H., Jekel, M., Keller, J., Kinzelbach, W., Kögel-Knabner, I., Liebl, W., Manhard, M., Mauser, W., Meckenstock, R., Menzel, A., Mok, B., Nießner, R., Rutschmann, P., Schmidt, T., Wegener, J., … Wilderer, P. (2012). Integrierter Ansatz zur Wasserforschung und Technologieentwicklung. Korrespondenz Abwasser, 59.
    22. Enzenhöfer, R., Nowak, W., & Helmig, R. (2012). Probabilistic exposure risk assessment with advective-dispersive well vulnerability criteria. Advances in Water Resources, 36. https://doi.org/10.1016/j.advatres.2011.04.018
    23. Jackson, A. S., Rybak, I., Helmig, R., Gray, W. G., & Miller, C. T. (2012). Thermodynamically constrained averaging theory approach for modeling flow and transport phenomena in porous medium systems: 9. Transition region model. Advances in Water Resources, 42. https://doi.org/10.1016/j.advwatres.2012.01.006
    24. Cirpka, O. A., Rolle, M., Chiogna, G., de Barros, F. P. J., & Nowak, W. (2012). Stochastic Evaluation of Mixing-Controlled Steady-State Plume Lengths in Two-Dimensional Heterogeneous Domains. Journal of Contaminant Hydrology, 138–139. https://doi.org/10.1016/j.jconhyd.2012.05.007
    25. Wolff, M., Flemisch, B., Helmig, R., & Aavatsmark, I. (2012). Treatment of tensorial relative permeabilities with multipoint flux approximation. International Journal of Numerical Analysis & Modeling, 9(3), Article 3. https://www.math.ualberta.ca/ijnam/Volume-9-2012/No-3-12/2012-03-14.pdf
    26. Tartakovsky, D. M., Nowak, W., & Bolster, D. (2012). Introduction to the special issue on uncertainty quantification and risk assessment. Advances in Water Resources, 36.
    27. Leube, P., Nowak, W., & Schneider, G. (2012). Temporal Moments revisited: Why there is there no better way for physically-based model reduction in time. Water Resources Research, 48. https://doi.org/10.1029/2012WR011973
    28. Kuhlmann, A., Neuweiler, I., van der Zee, S. E. A. T. M., & Helmig, R. (2012). Influence of soil structure and root water uptake strategy on steady state unsaturated flow in heterogeneous media. Water Resources Research, 48(2), Article 2. https://doi.org/10.1029/2011WR010651
    29. Baber, K., Mosthaf, K., Flemisch, B., Helmig, R., Müthing, S., & Wohlmuth, B. I. (2012). Numerical scheme for coupling two-phase compositional porous-media flow and one-phase compositional free flow. IMA Journal of Applied Mathematics, 77. https://doi.org/10.1093/imamat/hxs048
    30. Nowak, W., Rubin, Y., & de Barros, F. P. J. (2012). A Hypothesis-Driven Approach to Optimal Site Investigation. Water Resources Research. https://doi.org/10.1029/2011WR011016

  13. 2011

    1. Cirpka, O. A., de Barros, F. P. J., Chiogna, G., & Nowak, W. (2011). Probability Density Function of Steady-State Concentration in Two-Dimensional Heterogeneous Porous Media. Water Resources Research, 47(W11523), Article W11523. https://doi.org/10.1029/2011WR010750
    2. Walter, L., Oladyshkin, S., Class, H., Darcis, M., & Helmig, R. (2011). A study on pressure evolution in a sand channel system during CO2 injection. Energy Procedia, 4.
    3. Fritz, J., Flemisch, B., & Helmig, R. (2011). Decoupled and multiphysics models for non-isothermal compositional two-phase flow in porous media. International Journal of Numerical Analysis & Modeling, 9(1), Article 1. https://www.math.ualberta.ca/ijnam/Volume-9-2012/No-1-12/2012-01-02.pdf
    4. Szymkiewicz, A., & Helmig, R. (2011). Comparison of conductivity averaging methods for one-dimensional unsaturated flow in layered soils. Advances in Water Resources, 34(8), Article 8. https://doi.org/10.1016/j.advwatres.2011.05.011
    5. Schäfer, F., Walter, L., Class, H., & Müller, C. (2011). The regional pressure impact of CO2 storage: a showcase study from the North German Basin. Environmental Earth Sciences. https://doi.org/10.1007/s12665-011-1184-8
    6. Neuweiler, I., Papafotiou, A., Class, H., & Helmig, R. (2011). Estimation of effective parameters for a two-phase flow problem in non-Gaussian heterogeneous porous media. Journal of Contaminant Hydrology, 120–121(1), Article 1. https://doi.org/10.1016/j.jconhyd.2010.08.001
    7. Schmid, K. S., Geiger, S., & Sorbie, K. S. (2011). Semianalytical solutions for cocurrent and countercurrent imbibitionand dispersion of solutes in immiscible two-phase flow. Water Resources Research, 47. https://doi.org/10.1029/2010WR009686
    8. Flemisch, B., Darcis, M., Erbertseder, K., Faigle, B., Lauser, A., Mosthaf, K., Müthing, S., Nuske, P., Tatomir, A., Wolff, M., & Helmig, R. (2011). DUMUX: DUNE for multi-phase, component, scale, physics, ... flow and transport in porous media. Advances in Water Resources, 34(9), Article 9. https://doi.org/10.1016/j.advwaters.2011.03.007
    9. Niessner, J., Berg, S., & Hassanizadeh, S. M. (2011). Comparison of two-phase Darcy’s law with a thermodynamically consistent approach. Transport in Porous Media.
    10. Hlawatsch, M., Leube, P., Nowak, W., & Weiskopf, D. (2011). Flow Radar Glyphs - Static Visualization of Unsteady Flow with Uncertainty. IEEE Transactions on Visualization and Computer Graphics, 17(12), Article 12. https://doi.org/10.1109/TVCG.2011.203
    11. Szymkiewicz, A., Helmig, R., & Neuweiler, I. (2011). Upscaling unsaturated flow in binary porous media with air entry pressure effects. Water Resources Research, 48. https://doi.org/10.1029/2011WR010893
    12. Szymkiewicz, A., Helmig, R., & Kuhnke, H. (2011). Two phase flow in heterogeneous porous media with non-wetting phase trapping. Transport in Porous Media, 86(1), Article 1. https://doi.org/10.1007/s11242-010-9604-x
    13. de Barros, F. P. J., Bolster, D., Sanchez-Vila, X., & Nowak, W. (2011). A Divide and Conquer Approach to Cope with Uncertainties, Human Health Risk and Decision Making in Contaminant Hydrology. Water Resources Research, 47(W05508), Article W05508. https://doi.org/10.1029/2010WR009954
    14. Cao, Y., Helmig, R., & Wohlmuth, B. I. (2011). A two-scale operator-splitting method for two-phase flow in porous media. Advances in Water Resources, 34(12), Article 12. https://doi.org/10.1016/j.advwatres.2011.07.002
    15. Cirpka, O. A., de Barros, F. P. J., Chiogna, G., Rolle, M., & Nowak, W. (2011). Stochastic Flux-Related Analysis of Transverse Mixing in Two-Dimensional Heterogeneous Porous Media. Water Resources Research, 47(W06515), Article W06515. https://doi.org/10.1029/2010WR010279
    16. Lauser, A., Hager, C., Helmig, R., & Wohlmuth, B. I. (2011). A new approach for phase transitions in miscible multi-phase flow in porous media. Advances in Water Resources, 34(8), Article 8. https://doi.org/10.1016, j.advwaters.2011.04.021
    17. Oladyshkin, S., & Panfilov, M. (2011). Hydrogen penetration in water through porous medium: application to a radioactive waste storage site. Environmental Earth Sciences, 64(4), Article 4. https://doi.org/10.1007/s12665-011-0916-0
    18. Oladyshkin, S., Class, H., Helmig, R., & Nowak, W. (2011). A concept for data-driven uncertainty quantification and its application to carbon dioxide storage in geological formations. Advances in Water Resources, 34. https://doi.org/10.1016/j.advwatres.2011.08.005
    19. Heiss, V., Neuweiler, I., Ochs, S. O., & Färber, A. (2011). Experimental investigation on front morphology for two-phase flow in heterogeneous porous media. Water Resources Research, W10528, Article W10528. https://doi.org/10.1029/2011WR010612
    20. Darcis, M., Class, H., Flemisch, B., & Helmig, R. (2011). Sequential model coupling for feasibility studies of CO2 storage in deep saline aquifers. Oil & Gas Science and Technology-Revue de l’IFP, 66(1), Article 1. https://doi.org/10.2516/ogst/2010037
    21. Tatomir, A., Szymkiewicz, A., Class, H., & Helmig, R. (2011). Modeling two phase flow in large scale fractured porous media with an extended multiple interacting continua method. Computer Modeling in Engineering & Sciences.
    22. Oladyshkin, S., Class, H., Helmig, R., & Nowak, W. (2011). An integrative approach to robust design and probabilistic risk assessment for CO2 storage in geological formations. Computational Geosciences, 15(3), Article 3. https://doi.org/10.1007/s10596-011-9224-8
    23. Cao, Y., Helmig, R., & Wohlmuth, B. I. (2011). Convergence of the multipoint flux approximation L-method for homogeneous media on uniform grids. Numerical Methods for Partial Differential Equations, 27(2), Article 2. https://doi.org/10.1002/num.20525
    24. Ahrenholz, B., Niessner, J., Helmig, R., & Krafczyk, M. (2011). Pore-scale determination of parameters for macro-scale modeling of evaporation processes in porous media. Water Resources Research, 47. https://doi.org/10.1029/2010WR009519
    25. Mosthaf, K., Baber, K., Flemisch, B., Helmig, R., Leijnse, T., Rybak, I., & Wohlmuth, B. I. (2011). A coupling concept for two-phase compositional porous-medium and single-phase compositional free flow. Water Resources Research, 47. https://onlinelibrary.wiley.com/doi/10.1029/2011WR010685/abstract

  14. 2010

    1. Triebenbacher, S., Kaltenbacher, M., Wohlmuth, B. I., & Flemisch, B. (2010). Applications of the Mortar Finite Element Method in Vibroacoustics and Flow Induced Noise Computations. Acustica, 96. https://www.ingentaconnect.com/content/dav/aaua/2010/00000096/00000003/art00013
    2. Troldborg, M., Nowak, W., Tuxen, N., Bjerg, P. L., Helmig, R., & Binning, P. J. (2010). Uncertainty evaluation of mass discharge estimates from a contaminated site using a fully Bayesian framework. Water Resources Research, 46(W12552), Article W12552. https://doi.org/10.1029/2010WR009227
    3. Kopp, A., Binning, P. J., Johannsen, K., Helmig, R., & Class, H. (2010). A contribution to risk analysis for leakage through abandoned wells in geological CO2 storage. Advances in Water Resources, 33(8), Article 8. https://doi.org/10.1016/j.advwatres.2010.05.001
    4. van Noorden, T. L., Pop, I. S., Ebigbo, A., & Helmig, R. (2010). An upscaled model for biofilm growth in a thin strip. Water Resources Research, 46. https://doi.org/10.1029/2009WR008217
    5. de Barros, F. P. J., & Nowak, W. (2010). On the Link Between Contaminant Source Release Conditions and Plume Prediction Uncertainty. Journal of Contaminant Hydrology, 116. https://doi.org/10.1016/j.jconhyd.2010.05.004
    6. Nowak, W., de Barros, F. P. J., & Rubin, Y. (2010). Bayesian Geostatistical Design: Task-driven optimal Site Investigation When the Geostatistical Model is Uncertain. Water Resources Research, 46(W03535), Article W03535. https://doi.org/10.1029/2009WR008312
    7. Skjælaaen, I., Ebigbo, A., Espedal, M., & Helmig, R. (2010). A model for transport of hydrogen sulfide in oil- and water-saturated porous media. Computing and Visualization in Science, 13(6), Article 6. https://doi.org/10.1007/s00791-010-0143-3
    8. Kempka, T., Kühn, M., Class, H., Frykman, P., Kopp, A., Nielsen, C. M., & Probst, P. (2010). Modelling of CO2 arrival time at Ketzin - Part I. International Journal of Greenhouse Gas Control, 4. https://doi.org/10.1016/j.ijggc.2010.07.005
    9. Ebigbo, A., Helmig, R., Cunningham, A. B., Class, H., & Gerlach, R. (2010). Modelling biofilm growth in the presence of carbon dioxide and water flow in the subsurface. Advances in Water Resources, 33(7), Article 7. https://doi.org/10.1016/j.advwatres.2010.04.004
    10. Flemisch, B., Kaltenbacher, M., Triebenbacher, S., & Wohlmuth, B. I. (2010). The equivalence of standard and mixed finite element methods in applications to elasto-acoustic interaction. SIAM Journal on Scientific Computing, 32(4), Article 4. https://epubs.siam.org/doi/abs/10.1137/090758507
    11. Nuske, P., Faigle, B., Helmig, R., Niessner, J., & Neuweiler, I. (2010). Modeling gas-water processes in fractures with fracture flow properties obtained through upscaling. Water Resources Research, 46. https://doi.org/10.1029/2009WR008076
    12. Nowak, W. (2010). Measures of Parameter Uncertainty in Geostatistical Estimation and Geostatistical Optimal Design. Mathematical Geosciences, 42(2), Article 2. https://doi.org/10.1007/s11004-009-9245-1
    13. Ochs, S. O., Class, H., Färber, A., & Helmig, R. (2010). Methods for predicting the spreading of steam below the water table during subsurface remediation. Water Resources Research, 46. https://doi.org/10.1029/2007WR006401
    14. Papafotiou, A., Sheta, H., & Helmig, R. (2010). Numerical modeling of two-phase hysteresis combined with an interface condition for heterogeneous porous media. Computational Geosciences, 14(2), Article 2. https://doi.org/10.1007/s10596-009-9151-0

  15. 2009

    1. Class, H., Dahle, H. K., & Helmig, R. (2009). Preface (to the Special Issue). Computational Geosciences, 13. https://doi.org/10.1007/s10596-009-9160-z
    2. Darcis, M., Class, H., & Flemisch, B. (2009). Coupling Models of Different Complexity for the Simulation of CO2 Storage in Saline Aquifers. Energy Procedia, 1. https://www.sciencedirect.com/science/article/pii/S187661020900232X
    3. Kopp, A., Class, H., & Helmig, R. (2009). Investigations on CO2 storage capacity in saline aquifers - Part 2: Estimation of storage capacity coefficients. International Journal of Greenhouse Gas Control, 3(3), Article 3. https://doi.org/10.1016/j.ijggc.2008.10.001
    4. Helmig, R., Weiss, A., & Wohlmuth, B. I. (2009). Variational inequalities for modeling flow in heterogeneous porous media with entry pressure. Computational Geosciences, 13(3), Article 3. https://doi.org/10.1007/s10596-008-9125-7
    5. Kopp, A., Class, H., & Helmig, R. (2009). Investigations on CO2 storage capacity in saline aquifers - Part 1: Dimensional analysis of flow processes and reservoir characteristics. International Journal of Greenhouse Gas Control, 3(3), Article 3. https://doi.org/10.1016/j.ijggc.2008.10.002
    6. Fritz, J., Nowak, W., & Neuweiler, I. (2009). Application of FFT-based Algorithms for Large-Scale Universal Kriging Problems. Mathematical Geosciences, 41, Article 41. https://doi.org/10.1007/s11004-009-9220-x
    7. Geiger, S., Matthäi, S., Niessner, J., & Helmig, R. (2009). Black-oil simulations for three-component - three-phase flow in fractured porous media. SPE Journal, 14(2), Article 2. https://doi.org/10.2118/107485-PA
    8. Kopp, A., Probst, P., Class, H., Hurter, S., & Helmig, R. (2009). Estimation of CO2 storage capacity coefficients in geologic formations. Energy Procedia, 1(1), Article 1. https://doi.org/10.1016/j.egypro.2009.02.060
    9. Haegland, H., Assteerawatt, A., Dahle, H. K., Eigestad, G. T., & Helmig, R. (2009). Comparison of cell- and vertex-centered discretization methods for flow in a two-dimensional discrete-fracture-matrix system. Advances in Water Resources, 32.
    10. Class, H., Ebigbo, A., Helmig, R., Dahle, H. K., Nordbotten, J. M., Celia, M. A., Audigane, P., Darcis, M., Ennis-King, J., Fan, Y., Flemisch, B., Gasda, S. E., Jin, M., Krug, S., Labregere, D., Naderi Beni, A., Pawar, R. J., Sbai, A., Thomas, S. G., … Wei, L. (2009). A benchmark study on problems related to CO2 storage in geologic formations: Summary and discussion of the results. Computational Geosciences, 13(4), Article 4. https://doi.org/10.1007/s10596-009-9146-x
    11. Pop, I. S., van Duijn, C. J., Niessner, J., & Hassanizadeh, S. M. (2009). Horizontal redistribution of fluids in a porous medium: the role of interfacial area in modeling hysteresis. Advances in Water Resources, 32(3), Article 3. https://doi.org/10.1016/j.advwatres.2008.12.006
    12. Cao, Y., Helmig, R., & Wohlmuth, B. I. (2009). Geometrical interpretation of the multipoint flux approximation L-method. International Journal for Numerical Methods in Fluids, 60(11), Article 11. https://doi.org/10.1002/fld.1926
    13. Ernst, R., Flemisch, B., & Wohlmuth, B. I. (2009). A multiplicative Schwarz method and its application to nonlinear acoustic-structure interaction. Mathematical Modelling and Numerical Analysis, 43, Article 43. https://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=8194552&fileId=S0764583X09000107
    14. Kurz, S., Auchmann, B., & Flemisch, B. (2009). Dimensional reduction of field problems in a differential-forms framework. COMPEL, 28(4), Article 4. https://www.emeraldinsight.com/doi/abs/10.1108/03321640910959008
    15. Niessner, J., & Hassanizadeh, S. M. (2009). Modeling kinetic interphase mass transfer for two-phase flow in porous media including fluid - fluid interfacial area. Transport in Porous Media. https://doi.org/10.1007/s11242-009-9
    16. Kopp, A., Ebigbo, A., Bielinski, A., Class, H., & Helmig, R. (2009). Numerical simulation of temperature changes caused by CO2 injection in geological reservoirs. Carbon dioxide sequestration in geological media - State of the science, 59, Article 59.
    17. Niessner, J., & Helmig, R. (2009). Multi-physics modeling of flow and transport in porous media using a downscaling approach. Advances in Water Resources, 32(6), Article 6. https://doi.org/10.1016/j.advwatres.2009.02.007
    18. Freiboth, S., Class, H., Helmig, R., Graf, T., Ehlers, W., Schwarz, V., & Vrettos, C. (2009). A model for multiphase flow and transport in porous media including a phenomenological approach to account for deformation - a model concept and its validation within a code intercomparison study (Nr. 3). 13(3), Article 3. https://doi.org/10.1007/s10596-008-9118-6
    19. Niessner, J., & Hassanizadeh, S. M. (2009). Non-equilibrium interphase heat and mass transfer during two-phase flow in porous media-theoretical considerations and modeling. Advances in Water Resources, 32.
    20. Nowak, W. (2009). Best Unbiased Ensemble Linearization and the Quasi-Linear Kalman Ensemble Generator. Water Resources Research, 45(W04431), Article W04431. https://doi.org/10.1029/2008WR007328
    21. Dogan, M. O., Class, H., & Helmig, R. (2009). Different concepts for the coupling of porous-media flow with lower-dimensional pipe flow. Computer Modeling in Engineering & Sciences, 53(3), Article 3. https://doi.org/10.3970/cmes.2009.053.207
    22. Sudharsan, N. M., Jambhekar, V. A., & Babu, V. (2009). A validation study of OpenFOAM using the supersonic flow in a mixed compression intake. Proceedings of the Institution of Mechanical Engineers, Part G: Journal of Aerospace Engineering, 224(6). https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/2012/JAER0651_Final_Accepted.pdf

  16. 2008

    1. Papafotiou, A., Helmig, R., Schaap, J., Lehmann, P., Kaestner, A., Flühler, H., Neuweiler, I., Hassanein, R., Ahrenholz, B., Tölke, J., Peters, A., & Durner, W. (2008). From the pore scale to the lab scale: 3D lab experiment and numerical simulation of drainage in heterogeneous porous media. Advances in Water Resources, 31(9), Article 9. https://doi.org/10.1016/j.advwatres.2007.09.006
    2. Vasin, M., Lehmann, P., Kaestner, A., Hassanein, R., Nowak, W., Helmig, R., & Neuweiler, I. (2008). Drainage in heterogeneous sand columns with different geometric structures. Advances in Water Resources, 31(9), Article 9. https://doi.org/10.1016/j.advwatres.2008.01.004
    3. Oladyshkin, S., Royer, J.-J., & Panfilov, M. (2008). Effective solution through the streamline technique and HT-splitting for the 3D dynamic analysis of the compositional flows in oil reservoirs. Transport in Porous Media, 74,No.3.
    4. Johannsen, K., Kopp, A., Tourunen, O., & Kleist, J. (2008). Studying CO2 Sequestration with the Power of Supercomputing. European Research Consortium for Informatics and Mathematics (ERCIM), 74.
    5. Nowak, W., Schwede, R., Cirpka, O. A., & Neuweiler, I. (2008). Probability density functions of hydraulic head and velocity in three-dimensional heterogeneous porous media. Water Resources Research, 44(W08452), Article W08452. https://doi.org/10.1029/2007WR006383
    6. Schwede, R., Cirpka, O. A., Nowak, W., & Neuweiler, I. (2008). Impact of Sampling Volume on the Probability Density Function of Steady-State Concentration. Water Resources Research, 44(W12433), Article W12433. https://doi.org/10.1029/2007WR006668
    7. Niessner, J., & Hassanizadeh, S. M. (2008). A model for two-phase flow in porous media including fluid-fluid interfacial area. Water Resources Research, 44(W08439), Article W08439. https://doi.org/10.1029/2007WR006721
    8. Bielinski, A., Kopp, A., Schütt, H., & Class, H. (2008). Monitoring of CO2 plumes during storage in geological formations using temperature signals: numerical investigation (Nr. 2). 2, Article 2. https://doi.org/10.1016/j.ijggc.2008.02.008
    9. Eder, M., Kobus, H., & Helmig, R. (2008). Dreidimensionale Modellierung der Hydrodynamik im Bodensee. Wasserwirtschaft, 98,1.
    10. Manthey, S., Hassanizadeh, S. M., Helmig, R., & Hilfer, R. (2008). Dimensional analysis of two-phase flow including a rate-dependent capillary pressure-saturation relationship. Advances in Water Resources, 31(9), Article 9. https://doi.org/10.1016/j.advwatres.2008.01.021
    11. Class, H., Helmig, R., & Neuweiler, I. (2008). Sequential coupling of models for contaminant spreading in the vadose zone. Vadose Zone Journal, 7(2), Article 2. https://doi.org/10.2136/vzj2007.0056

  17. 2007

    1. Hurter, S., Garnett, A., Bielinski, A., & Kopp, A. (2007). Thermal Signature of Free-Phase CO2 in Porous Rocks: Detectability of CO2 by Temperature Logging (Nr. SPE109007). SPE109007, Article SPE109007.
    2. Ebigbo, A., Class, H., & Helmig, R. (2007). CO2 leakage through an abandoned well: Problem-oriented benchmarks (Nr. 2). 11(2), Article 2. https://doi.org/10.1007/s10596-006-9033-7
    3. Helmig, R., Weiss, A., & Wohlmuth, B. I. (2007). Dynamic capillary effects in heterogeneous porous media (Nr. 3). 11(3), Article 3. https://doi.org/10.1007/s10596-007-9050-1
    4. Flemisch, B., & Wohlmuth, B. I. (2007). Stable Lagrange multipliers for quadrilateral meshes of curved interfaces in 3D. Computational Methods in Applied Mechanical Engineering, 196. https://doi.org/10.1016/j.cma.2006.03.022
    5. van Duijn, C. J., Eichel, H., Helmig, R., & Pop, I. S. (2007). Effective equations for two-phase flow in porous media: the effect of trapping on the microscale. Transport in Porous Media, 69(3), Article 3. https://doi.org/10.1007/s11242-006-9089-9
    6. Neuweiler, I., & Vogel, H.-J. (2007). Upscaling for unsaturated flow for non-Gaussian heterogeneous porous media. Water Resources Research, 43.
    7. Oladyshkin, S., & Panfilov, M. (2007). Limit thermodynamic model for compositional gas-liquid systems moving in a porous medium. Transport in Porous Media, 70,No.2.
    8. Oladyshkin, S., & Panfilov, M. (2007). Streamline splitting between thermodynamics and hydrodynamics in compositional gas-liquid flow through porous media. 335,No.1.
    9. Oladyshkin, S., Skachkov, S., Panfilova, I., & Panfilov, M. (2007). Upscaling fractured media and streamline HT-splitting in compositional reservoir simulation. Oil & Gas Science and Technology-Revue de l’IFP, 62,No.2.
    10. Niessner, J., & Helmig, R. (2007). Multi-scale modeling of three-phase--three-component processes in heterogeneous porous media. Advances in Water Resources, 30(11), Article 11. https://doi.org/10.1016/j.advwatres.2007.05.008
    11. Kobayashi, K., Hinkelmann, R., Helmig, R., Takara, K., & Tamai, N. (2007). A numerical experiment with two-phase and two-phase/three-component models for the methane migration in the subsurface aquifer (Nr. 2). 63(2), Article 2.

  18. 2006

    1. Nowak, W., & Cirpka, O. A. (2006). Geostatistical inference of hydraulic conductivity and dispersivities from hydraulic heads and tracer data (Nr. W08416). 42(W08416), Article W08416. https://doi.org/10.1029/2005WR004832
    2. Helmig, R., Niessner, J., & Class, H. (2006). Recent advances in finite element methods for multi-phase flow processes in porous media (03_04). 20(03_04), Article 03_04. https://doi.org/10.1080/00036810600792154
    3. Kopp, A., & Sheta, H. (2006). Grid Generation for Complex Geological Systems in Mining Areas. https://www.iws.uni-stuttgart.de/publikationen/hydrosys/paper/kopp21-AB.pdf
    4. Helmig, R., Sheta, H., Meiners, H., & Kunz, E. (2006). Numerische Simulation von Gasströmen im Grubengebäude und im Gebirge (01_02). 142(01_02), Article 01_02.
    5. Neuweiler, I., & Vogel, H.-J. (2006). Upscaling of unsaturated flow considering connectivity.
    6. Neuweiler, I., & Eichel, H. (2006). Effective parameter functions for Richards equation in layered porous media (Nr. 5). 5, Article 5.
    7. Acosta, M., Merten, C., Eigenberger, G., Class, H., Helmig, R., Thoben, B., & Müller-Steinhagen, H. (2006). Modeling non-isothermal two-phase multicomponent flow in the cathode of PEM fuel cells (Nr. 2). 2, Article 2. https://doi.org/10.1016/j.jpowsour.2005.12.068
    8. Niessner, J., & Helmig, R. (2006). Multi-scale modeling of two-phase - two-component processes in heterogeneous porous media. Numerical Linear Algebra with Applications, 13(9), Article 9. https://doi.org/10.1002/nla.497
    9. Reichenberger, V., Jakobs, H., Bastian, P., & Helmig, R. (2006). A mixed-dimensional finite volume method for two-phase flow in fractured porous media. Advances in Water Resources, 29(7), Article 7. https://doi.org/10.1016/j.advwatres.2005.09.001
    10. Class, H., Bielinski, A., Helmig, R., Kopp, A., & Ebigbo, A. (2006). Numerische Simulation der Speicherung von CO2 in geologischen Formationen (Nr. 4). 78(4), Article 4.
    11. Flemisch, B., Kaltenbacher, M., & Wohlmuth, B. I. (2006). Elasto-acoustic and acoustic-acoustic coupling on nonmatching grids. International Journal of Numerical Methods in Engineering, 67. https://doi.org/10.1002/nme.1669

  19. 2005

    1. Haas, T. (2005). Wir sind nun Orientalen geworden. Die Anfänge der Kreuzfahrerherrschaften. 11_05.
    2. Manthey, S., Hassanizadeh, S. M., & Helmig, R. (2005). Macro-scale dynamic effects in homogeneous and heterogeneous porous media (01_02). 58(01_02), Article 01_02. https://doi.org/10.1007/s11242-004-5472-6
    3. Flemisch, B., Melenk, J. M., & Wohlmuth, B. I. (2005). Mortar methods with curved interfaces. Applied Numerical Mathematics, 54. https://doi.org/10.1016/j.apnum.2004.09.007
    4. Rahman, A. Md., Jose Chackiath, S., Nowak, W., & Cirpka, O. A. (2005). Experiments on vertical transverse mixing in a large-scale heterogeneous model aquifer (Nr. 80). 03_04(80), Article 80. https://doi.org/10.1016/j.jconhyd.2005.06.010
    5. Flemisch, B., Maday, Y., Rapetti, F., & Wohlmuth, B. I. (2005). Scalar and vector potentials’ coupling on nonmatching grids for the simulation of an electromagnetic brake. COMPEL, 24. https://doi.org/10.1108/03321640510571246
    6. Mödinger, J., & Kobus, H. (2005). Approach and Methods for the Assessment of Sustainable Groundwater Management in the Rhine-Neckar-Region, Germany (Nr. 3). 21(3), Article 3.
    7. Neuweiler, I., & Cirpka, O. A. (2005). Homogenization of Richards Equation in Permeability Fields with Different Connectivities (Nr. 2). 41(2), Article 2. https://doi.org/10.1029/2004WR003329
    8. Flemisch, B., Puso, M. A., & Wohlmuth, B. I. (2005). A new dual mortar method for curved interfaces: 2D elasticity. International Journal of Numerical Methods in Engineering, 63. https://doi.org/10.1002/nme.1300
    9. Braun, C., Helmig, R., & Manthey, S. (2005). Macro-scale effective constitutive relationships for two-phase flow processes in heterogeneous porous media with emphasis on the relative permeability-saturation-relationship (01_02). 76(01_02), Article 01_02. https://doi.org/10.1016/j.jconhyd.2004.07.009
    10. Li, W., Nowak, W., & Cirpka, O. A. (2005). Geostatistical inverse modeling of transient pumping tests using temporal moments of drawdown (Nr. W08403). 41(W08403), Article W08403. https://doi.org/10.1029/2004WR003874
    11. Niessner, J., Helmig, R., Jakobs, H., & Roberts, J. (2005). Interface condition and linearization schemes in the Newton iterations for two-phase flow in heterogeneous porous media (Nr. 7). 28(7), Article 7. https://doi.org/10.1016/j.advwatres.2005.01.006

  20. 2004

    1. Findikatis, A., Helmig, R., Kitanidis, P. K., Nimmo, J., Pruess, K., Rubin, Y., Stauffer, F., & Tsang, C.-F. (2004). Summary of a panel discussion at the International Groundwater Symposium held onMarch 25-28. 2002 Berkeley, Califorina, USA (03_04). 42(03_04), Article 03_04.
    2. Neuweiler, I., Sorensen, I., & Kinzelbach, W. (2004). Experimental and theoretical investigations of drainage in horizontal rough-walled fractures with different correlation structures (Nr. 12). 27(12), Article 12.
    3. Hinkelmann, R., Paul, M., Helmig, R., & Breiting, T. (2004). New media in environmental and water-related engineering education (Nr. 2). 13(2), Article 2.
    4. Flemisch, B., & Wohlmuth, B. I. (2004). A domain decomposition method on nested domains and nonmatching grids. Numerical Methods for Partial Differential Equations, 20. https://doi.org/10.1002/num.10095
    5. Cirpka, O. A., Olsson, Ĺ., Ju, Q., Rahman, A. Md., & Grathwohl, P. (2004). Length of Reactive Plumes Controlled by Transverse Dispersion. https://www.ncbi.nlm.nih.gov/pubmed/16556203
    6. Flemisch, B., Maday, Y., Rapetti, F., & Wohlmuth, B. I. (2004). Coupling scalar and vector potentials on non-matching grids for eddy currents modelling in a moving conductor. Journal of Computational and Applied Mathematics, 168. https://doi.org/10.1016/j.cam.2003.05.017
    7. Cirpka, O. A., Bürger, C. M., Nowak, W., & Finkel, M. (2004). Uncertainty and data worth analysis for the hydraulic design of funnel-and-gate systems in heterogeneous aquifers (Nr. 40). W11502(40), Article 40. https://doi.org/10.1029/2004WR003352
    8. Benekos, I., Cirpka, O. A., Rahman, A. Md., & Kitanidis, P. K. (2004). Experimental determination of transverse dispersion parameters in a helical device.
    9. Mödinger, J., Kobus, H., Schnitzler, S., & Lehn, H. (2004). Ansätze für eine nachhaltige Grundwasserbewirtschaftung und -nutzung im Rhein-Neckar-Raum bei konkurrierenden Interessen. 94.
    10. Hilfer, R., & Helmig, R. (2004). Dimensional analysis and upscaling of two-phase flow in porous media with piecewise constant heterogeneities (Nr. 10). 27(10), Article 10. https://doi.org/10.1016/j.advwatres.2004.07.003
    11. Cirpka, O. A., & Nowak, W. (2004). First-Order Variance of Travel Time in Non-Stationary Formations (W03507(3)). 40(W03507(3)), Article W03507(3). https://doi.org/10.1029/2003WR002851
    12. Jose Chackiath, S., Rahman, A. Md., & Cirpka, O. A. (2004). Large-scale sandbox experiment on longitudinal effective dispersion in heterogeneous porous media. https://onlinelibrary.wiley.com/doi/10.1029/2004WR003363/full
    13. Hazra, S. B., Class, H., Helmig, R., & Schulz, V. (2004). Forward and inverse problems in modeling of multiphase flow and transport through porous media (Nr. 1). 8(1), Article 1. https://doi.org/10.1023/B:COMG.0000024445.39048.21

  21. 2003

    1. Neuweiler, I., Sorensen, I., & Kinzelbach, W. (2003). Impact of correlation structure on drainage in open rough-walled fractures (Nr. 3). 1(3), Article 3.
    2. Neuweiler, I., Attinger, S., Kinzelbach, W., & King, P. (2003). Large scale mixing for immiscible displacement in heterogeneous porous media. 51.

  22. 2002

    1. Burchardi, F., & Memminger, B. (2002). Monetarisierung von umweltrelevanten Sachverhalten bei der Verkehrswertermittlung eines aktiven Produktionsstandortes - ein Praxisfall (Nr. 4). 4, Article 4.
    2. King, P., & Neuweiler, I. (2002). Probability upscaling. 6.

  23. 2001

    1. Schrenk, V., Schlicher, T., & Barczewski, B. (2001). Interdisciplinary Research Activities in Brownfield Redevelopment in the Federal State of Baden Württemberg, Germany. Brownfields 2001.
    2. Schrenk, V., Schlicher, T., & Barczewski, B. (2001). Arbeitsgruppe FIGURA stellt sich vor. Flächenrecycling, Industriebrachen, Grundwasserschutz - Umweltgerechte Revitalisierung von Altstandorten.
    3. Attinger, S., Neuweiler, I., & Kinzelbach, W. (2001). Macrodispersion in a radially diverging flow field with finite Peclet numbers, 2.: Homogenization theory approach (Nr. 3). 37(3), Article 3.
    4. Kobus, H. (2001). Forschungsbericht 1994 - 2002 des Lehrstuhls für Hydraulik und Grundwasser.
    5. Schlicher, T., Schrenk, V., & Barczewski, B. (2001). Projekt „EDV Tool“. Entwicklung einer EDV gestützten Bewertungsmatrix und Datenbank zur Ableitung übertragbarer Kriterien für ein systematisiertes Flächenrecycling in Baden Württemberg (BWC 99003).
    6. Neuweiler, I., Attinger, S., & Kinzelbach, W. (2001). Macrodispersion in a radially diverging flow field with finite Peclet numbers, 1.: Perturbation theory approach (Nr. 3). 37(3), Article 3.

  24. 2000

    1. Juckenack, C. C., Barczewski, B., & Schrenk, V. (2000). Flächenressourcen-Management in Baden-Württemberg (Nr. 5). 5, Article 5.
    2. Juckenack, C. C., Barczewski, B., & Schrenk, V. (2000). Recycling Derelict Land and Site Management in Agglomerations - the Cooperative FIGURA.
    3. Barczewski, B., Batereau, K., Juckenack, C. C., Klaas, N., Schlicher, T., & Schrenk, V. (2000). Strukturierung von Flächenrecycling in Baden-Württemberg. Erste Vorhaben des Projektverbundes FIGURA starten.

  25. 1999

    1. Schrenk, V., & Juckenack, C. C. (1999). Flächenrecycling in Baden-Württemberg. Foschungsprojekte der Arbeitsgruppe FIGURA gestartet.
    2. Juckenack, C. C., Barczewski, B., & Schrenk, V. (1999). Flächenrecycling und Flächenmanagement in Ballungsräumen. Ein Ansatz zur Strukturierung: der Projektverbund „FIGURA“ in Baden-Württemberg (Nr. 5). 5, Article 5.
    3. Metzger, D., Kinzelbach, H., Neuweiler, I., & Kinzelbach, W. (1999). Asymptotic transport parameters in a heterogeneous porous medium: Comparison of two ensemble-averaging procedures. 13.

  26. 1998

    1. Kern, U., Li, C. C., & Westrich, B. (1998). Assessment of Sediment contamination frorn pollutant discharge in surface waters (06_07). 37(06_07), Article 06_07.
    2. Kobus, H. (1998). Groundwater Management Problems (01_02). 01_02, Article 01_02.
    3. Juckenack, C. C. (1998). Flächenrecycling in Baden-Württemberg - Der Projektverbund FIGURA (Flächenrecycling, Industriebranchen, Grundwasserschutz - Umweltgerechte Revitalisierung von Altstandorten (Nr. 4). 4, Article 4.

  27. 1997

    1. Färber, A., Betz, C., & Schmidt, R. (1997). In-situ-Sanierungsverfahren durch Dampf im halbtechnischen Maßstab (Nr. 1). 1, Article 1.
    2. Kobus, H. (1997). A Desafíos en Hidráulica para el Siglo XXI (Nr. 1). 4(1), Article 1.
    3. Kobus, H. (1997). Globalisierung der Wasserwirtschaft: Herausforderung für die universitäre Ausbildung.
    4. Klaas, N., Simmank, S., & Rademacher, C. (1997). Erfahrungen bei der Methodenentwicklung in der Kapillarelektrophorese (Nr. 6). 6, Article 6.

  28. 1996

    1. Barczewski, B., Käss, W., Schmid, G., & Werner, A. (1996). Neue Möglichkeiten und Anwendungen der Grundwassermarkierungstechnik (Nr. 1). 85(1), Article 1.
    2. Barczewski, B., Kritzner, W., & Nitsche, C. (1996). Tiefenorientierte Grundwasserprobenahme zur Messung der Wasserbeschaffenheit (Nr. 9). 85(9), Article 9.
    3. Kobus, H., Plate, E. J., Shen, H. W., & Szöllösi Nagy, A. (1996). Education of Hydraulic Engineers. International Hydrological Programme.
    4. Kobus, H. (1996). Boden- und Grundwasserschutz - Voraussetzung für eine nachhaltige Wasserwirtschaft (Nr. 2). 86(2), Article 2.
    5. Betz, C., & Färber, A. (1996). Physikalische Prozesse bei thermischer In-situ-Sanierung mit Dampf (Nr. 6). 6, Article 6.

  29. 1995

    1. Barczewski, B. (1995). Datensammler für die Grundwassermessung - Grundstruktur, Entwicklung und heutiger Stand (Nr. 4). 4, Article 4.
    2. Kobus, H., & Koschitzky, H.-P. (1995). Wasserwirtschaft und Verkehrswege: Die Schnellbahntrasse Stuttgart-Ulm (Nr. 68). 68, Article 68.

  30. 1994

    1. Kobus, H. (1994). Neuere Erkenntnisse aus der Grundwasserforschung - Eintrag und Transport von Stoffen. DVGW-LAWA Kolloquium „Flächendeckender Grundwasserschutz und Grundwasserschutzgebiete“, 84, Article 84.
    2. Kobus, H., Plate, E. J., Shen, H. W., & Szöllösi Nagy, A. (1994). La Formación del Ingeniero Hidráulico (Nr. 3). 1(3), Article 3.
    3. Keim, B., Barczewski, B., & Juraschek, M. (1994). Überwachung von Wasserbeschaffenheit und Schüttung von Quellen - Aufbau der Pilotmessstationen und erste Ergebnisse aus dem Quellmessnetz Baden-Württemberg (Nr. 5). 84(5), Article 5.

  31. 1993

    1. Barczewski, B., Grimm-Strele, J., & Bisch, G. (1993). Überprüfung der Eignung von Grundwasserbeschaffenheitsmessstellen (Nr. 2). 83(2), Article 2.

  32. 1992

    1. Kobus, H. (1992). Schadstoffbelastungen des Grundwassers und Schutzmaßnahmen für die Wasserversorgung. Wechselwirkungen.

  33. 1991

    1. Kobus, H. (1991). Contributions to „Hydraulics and the Environment, Partnership in Sustainable Development“. IAHR Workshop on Matching hydraulics and ecology in water systems, 14.03.1991 - 16.03.1991, Utrecht, The Netherlands, 29.
    2. Barczewski, B. (1991). Ein neuer faseroptischer Sensor für Geschwindigkeits- und Durchflussmessungen (technical note) (Nr. 24). 24, Article 24.
    3. Kobus, H. (1991). Grundwasserqualität und Umweltschadstoffe. Lebendige Wissenschaft, 28.07.1991.

  34. 1990

    1. Kobus, H. (1990). Den Schadstoffen auf der Spur, Transportprozesse im Grundwasser.
    2. Kobus, H. (1990). On the Track of Soil Pollutants, Transport Processes in Ground Water.
    3. Barczewski, B., & Marschall, P. (1990). Untersuchungen zur Probenahme in Grundwassermessstellen (Nr. 10). 80(10), Article 10.
    4. Kobus, H. (1990). Hydraulische Sanierungsverfahren. „Altlasten“, Fachvorträge des ATV-Seminars Altlasten, 10.05.1989 - 11.05.1989.
    5. Barczewski, B. (1990). Optische Methoden zur in-situ Tracerkonzentrationsmessung in Strömungen (Nr. 11). 80(11), Article 11.

  35. 1989

    1. Marschall, P., & Barczewski, B. (1989). The Analysis of Slug-Tests in Frequency Domain (Nr. 11). 25(11), Article 11.
    2. Koschitzky, H.-P. (1989). Der Beginn des Lufteintrags bei Sohlnischen mit Rampe (Nr. 10). 10, Article 10.

  36. 1988

    1. Kobus, H. (1988). Das PWAB-Testfeld Wasser und Boden. 1. Statuskolloquium des PWAB (Projekt Wasser, Abfall, Boden), 23.02.1988, Karlsruhe.
    2. Koschitzky, H.-P. (1988). Dimensionierung von Schußrinnenbelüftern (Nr. 5). 5, Article 5.
    3. Kobus, H. (1988). Vorwort zum Sonderheft. Sicherheit von Hochwasserrückhaltebecken: Hydrologische und hydraulische Entwurfsgrundlagen und Bemessungsrichtlinien, 78(1), Article 1.
    4. Kobus, H. (1988). Grundwasserbelastungen, Sanierungsbeispiele und Schutzmaßnahmen.

  37. 1987

    1. Kobus, H. (1987). Ein Programm zur Erforschung aktueller Probleme in Grundwasserwirtschaft und Grundwasserschutz (Nr. 11). 77(11), Article 11.

  38. 1986

    1. Kobus, H. (1986). Unterrichtsmaterialien. Weiterbildungsstudium Hydrologie-Wasserwirtschaft.
    2. Kobus, H. (1986). Nitrat und Biozide im Grundwasser und Konsequenzen für die Trinkwassergewinnung. Umwelt, Wirtschaft, Gesellschaft - Wege zu einem neuen Grundverständnis.

  39. 1984

    1. Kobus, H. (1984). Grundwasserverunreinigungen durch Chlorkohlenwasserstoffe (Nr. 2). 2, Article 2.
    2. Barczewski, B., & Grimm-Strele, J. (1984). Echolotung in verschlammten Gewässern.

  40. 1983

    1. Barczewski, B., & Juraschek, M. (1983). Ermittlung der Abflussbeziehung von Venturigerinnen (Nr. 5). 73(5), Article 5.
    2. Kobus, H., & Barczewski, B. (1983). Durch Luftblasen erzeugte Auftriebsstrahlen (Nr. 11). 73(11), Article 11.
    3. Kobus, H. (1983). Berechnungsgrundlagen für Wärmeausbreitung und -transport im Grundwasser. 52.

  41. 1981

    1. Kobus, H. (1981). Strömungsmechanische Grundlagen des Transports der Halogenkohlenwasserstoffe in Grundwasserleitern - Maßnahmen zur Erfassung des verunreinigten Wassers (Nr. 29). 29, Article 29.

  42. 1979

    1. Kobus, H. (1979). Wassernutzung für Kühlzwecke (Nr. 5). 69(5), Article 5.

  43. 1978

    1. Kobus, H. (1978). Fluid-Mechanic Aspects in the Design of Sewage Outfalls into the Sea. 12.

  44. 1977

    1. Kobus, H. (1977). Tätigkeitsbericht des Sonderforschungsbereichs 80 1975/76.

  45. 1976

    1. Kobus, H. (1976). Beschreibung von Einleitungsvorgängen in Gewässern in Umweltschutz im Bereich des Wasserbaus. Wasser und Abwasser in Forschung und Praxis, 14.
    2. Kobus, H. (1976). Strömungsmechanische Entwurfsaspekte für Abwassereinleitungen ins Meer, Erwiderung zu einem Diskussionsbeitrag von Prof. Dr.-Ing. K. Krauth, Stuttgart.
    3. Kobus, H. (1976). Strömungsmechanische Entwurfsaspekte für Abwassereinleitungen ins Meer (Nr. 5). 5, Article 5.

  46. 1974

    1. Kobus, H. (1974). Anwendung der Dimensionsanalyse in der experimentellen Forschung des Bauingenieurwesens (Nr. 3). 3, Article 3.
    2. Kobus, H. (1974). Ausbreitungsvorgänge in Gewässern - Ein Reisebericht über Forschungsarbeiten in den USA im Jahr 1973/74.

  47. 1973

    1. Kobus, H. (1973). Erosion durch einen pulsierenden Strahl.
    2. Kobus, H. (1973). Berechnungsmethode für Luftschleier-Strömungen zur Auslegung von Preßluft-Ölsperren, Erwiderung zu einem Diskussionsbeitrag von Dr.-Ing. E. Stehr, Hamburg.
    3. Kobus, H. (1973). Luftschleier in einer Querströmung.

  48. 1972

    1. Kobus, H. (1972). Berechnungsmethode für Luftschleier-Strömungen zur Auslegung von Preßluft-Ölsperren.

  49. 1971

    1. Kobus, H. (1971). Luftschleier in einer Querströmung. Ausbreitungs- und Transportvorgänge in Strömungen.
    2. Kobus, H. (1971). Einfluß einer pulsierenden Strömung auf die Erosion eines Sedimentbetts. Ausbreitungs- und Transportvorgänge in Strömungen.
    3. Kobus, H. (1971). Diskussionsbeitrag zu „Durchströmungsmessungen in Roh- und Reinwasserbehältern von Wasserversorgungsanlagen“, von G. Marotz und H. E. Minor.

  50. 1970

    1. Kobus, H. (1970). Diskussionsbeitrag zu „Jet-Induced Circulation and Diffusion“, von C. Iamandi und H. Rouse.

  51. 1969

    1. Kobus, H. (1969). Untersuchungen über die Verminderung der besonders sinkstoffreichen Dichteströmungen in Brackwassergebieten durch Luftblasenschleier (Nr. 50). 50, Article 50.

  52. 1967

    1. Kobus, H. (1967). Examination of Eggers Relationship between Transverse Wave Profiles and Wave Resistance.

  53. 1965

    1. Kobus, H. (1965). Air-Tunnel Model Study of Fort Martin Cooling Tower (Nr. 108). 108, Article 108.

  54. 1963

    1. Class, H., Mahl, L., Ahmed, W., Norden, B., Kühn, M., & Kempka, T. (1963). Matching pressure measurements and observed CO2 arrival times with static and dynamic modelling at the Ketzinstorage site.

studentische Arbeiten betreut am LH2

  1. 2022

    1. Coupled Turbulent Free- and Porous Media Flows: Investigations of Interfacial Roughness. (2022). (mastersthesis).
    2. Accurate Flow Boundary Conditions for the Lattice Boltzmann Method. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    3. Modeling the use of microbially induced calcite precipitation for road construction. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    4. Numerical Modeling of Biocement Production. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    5. Coupling between a detailed model and a large-scale model for exchanging density-dependent salt fluxes. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    6. Numerische Simulation des wärmegekoppelten Stofftransports durch die Speicherhülle eines Erdbeckenspeichers. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    7. Biofilm-Visualisierung in mikrofluidischen Zellen. (2022). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    8. Untersuchung einer modifizierten Allen-Cahn-Gleichung ohne krümmungsbedingte Bewegung. (2022). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    9. Coupled flow, transport, and geochemical processes in karstic fractures. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    10. Coupled Free-Flow and Porous Media Flow Systems: Analysis of Turbulent Free-Flow Condtions and Pore-Network Models. (2022). (Forschungsmodul2).
    11. Thermodynamic Analysis of Carbon Dioxide Mass Transport in a Stagnant Water Column. (2022). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    12. Analysis of the Stefan flow problem and comparison to an advection-diffusion formulation. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    13. Combining a monolithic implementation of a locally-refined finite-volume staggered-grid method for the incompressible Navier-Stokes equations with an implementation of a SIMPLE-type solution algorithm. (2022). (Bachelorarbeit und Propädeutikum).
    14. Modeling of mechanical response to microbially induced calcite precipitation in porous media. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.

  2. 2021

    1. A 0-dimensional conceptual model to facilitate coupling of groundwater and surface-water numerical models - and its application to a bog-wetland study area. (2021). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    2. Density-driven dissolution of CO2 in karst water - longterm monitoring and modelling in a water column. (2021). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    3. Implementing and testing a standard black oil model in Dumux. (2021). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    4. Herleitung reduzierter Modelle einer Zweiphasenströmung zwischen parallelen Platten mit Slip-Bedingungen. (2021). (Projektarbeit).
    5. Averaged Analysis of Pore Scale Dynamics via Closure Problems. (2021). (Forschungsmodul 2).
    6. Discretizing free flow coupled to porous-medium flow by a locally-refined finite-volume staggered-grid method using an interface with refined pressures and coarse velocities. (2021). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    7. Modellierung von Deponien mit schwach radioaktivem Material. (2021). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    8. Flow in diffusive transition zones. (2021). (Projektarbeit).
    9. Vergleich des Lösens der Navier-Stokes Gleichungen auf lokal verfeinerten versetzten Gittern in den Softwarepakete DuMux und IBAMR. (2021). (Projektarbeit).
    10. Linear stability analysis for an evaporation problem of a porous slab. (2021). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    11. Numerical study on the modelling of macropores. (2021). (Master Thesis).
    12. Investigation of linear solvers and preconditioners for sparse systems resulting from free-flow applications. (2021). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    13. Die Finite-Volumen-Methode am Beispiel der Konvektions-Diffusions-Gleichung. (2021). (Seminararbeit).
    14. Experimental Investigation on the Impact of Induced Calcite Precipitation on Two-Phase Flow. (2021). (Bachalorarbeit).
    15. Experimentelle Untersuchung von mikrobiologisch induzierter Kalkausfällung in mikrofluidischen Zellen. (2021). (Bachalorarbeit).
    16. Experimentelle Untersuchung von induzerter Calcitausfällung. (2021). (Master’s Thesis).
    17. Modelling Turbulence in Coupled Environments: The K-Shear Stress Transport Model. (2021). (Master’s Thesis).
    18. Modeling calcite dissolution due to density-induced fingering of CO2-enriched water. (2021). (Master’s Thesis).
    19. SIMPLE-type methods for iteratively solving the Navier-Stokes equations. (2021). (Forschungsmodul 1). Universität Stuttgart.
    20. Transport Properties from Entropy Scaling using PC-SAFT Equation of State for the Modelling of Subsurface Hydrogen Storage. (2021). (Masterarbeit). Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung, Universität Stuttgart.
    21. Modeling of temperature-dependent mineral precipitation and dissolution in porous media. (2021). (Forschungsmodul).

  3. 2020

    1. Numerical investigation of fracture dilation processes in radioactive waste storage sites. (2020). (Masterarbeit). Institut für Wasser-und Umweltsystemmodellierung Lehrstuhl für Hydromechanik und Hydrosystemmodellierung, Universität Stuttgart.
    2. Mixed-dimension coupling methods with distributed sources for two phase flow problems in porous media. (2020). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    3. Untersuchung des lokalen thermischen Nicht-Gleichgewichts bei der thermochemischen Wärmespeicherung. (2020). (Projektarbeit). Universität Stuttgart.
    4. Entwicklung eines Stoffmodells für Wasserstoff unter überkritischen Bedingungen zur Analyse von Wasserstoffspeicherung im Untergrund. (2020). (Bachalorarbeit).
    5. Kalibrierung eines realistischen Grundwassermodells mit FEPEST. (2020). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    6. Combination of a locally-refined quadtree finite-volume staggered grid scheme for the Navier-Stokes equation with turbulence models. (2020). (Forschungsmodul 2).
    7. Extension of a locally-refined quadtree finite-volume staggered-grid scheme to a drop-on-wall geometry. (2020). (Forschungsmodul 1).
    8. Effective heat transfer models in thin porous media. (2020). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    9. Untersuchung von Rissstrukturen bei der thermochemischen Wärmespeicherung mit CaO/Ca(OH)2. (2020). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    10. Grundlagenuntersuchung zum saugseitigen Filter im DNOX-Fördermodul. (2020). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.

  4. 2019

    1. Pore and pore-network scale modeling on realistic geometries extracted from CT images. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    2. Development of interface criteria for model reduction strategies for the simulation of hydrogen storage. (2019). (Masterarbeit). Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung, Universität Stuttgart.
    3. Numerische Ermittlung der Ergiebigkeit von Brunnen unter Berücksichtigung der Forchheimer-Gleichung und Darstellung der Ergebnisse in dimensionsloser Form / Numerical simulation of well yield using the forchheimer equation and presentation of the results by dimensionless numbers. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    4. Decoupled solution of flow, transport and reactions for microbially enhanced coal bed methane scenarios. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    5. A dual pore-network model for fluid and energy transport in soils considering thermal non-equilibrium. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    6. Examination of Mass Transfer Effects in Redox Flow Batteries by means of Analytical Modelling. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    7. Experimental and numerical investigation of tracer transport in porous media on the pore scale. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    8. Quantifying similarities between computational expensive reactive transport models. (2019). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    9. Non-isothermal effects in Compressed Air Energy Storage systems. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    10. Modelling of Isotope Transport and Evaporation Rates at the Porous Medium Free-Flow Interface. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    11. Vergleich von Mehrkomponentendiffusionsansätzen im Kontext der Anwendung auf Brennstoffzellen. (2019). (bachelor thesis).
    12. Modelling and Simulation of the Thermal Utilization of Shallow Groundwater. (2019). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    13. Sensitivitätsanalyse eines reaktiven Transportmodells. (2019). (Projektarbeit).
    14. Numerische Simulation von Konvektion durch in Wasser gelöstes CO2. (2019). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    15. Instability analysis for salt precipitation processes in unsaturated porous media. (2019). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    16. Theorie und Erfahrung mit dem Gmsh Generator. (2019). (Seminararbeit).
    17. A fully implicit formulation for Navier-Stokes/Darcy coupling. (2019). (Masterthesis). Abgerufen von https://www.politesi.polimi.it/bitstream/10589/146077/1/2019_04_Vescovini.pdf
    18. Sensitivitätsanalyse für ein Modell zur mikrobiell erhöhten Methanproduktion in Kohleflözen. (2019). (Bacherlorarbeit).
    19. Implementierung eines numerischen Modells für den Transport von Tracerkomponenten in Zweiphasenströmungen. (2019). (Studienarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.

  5. 2018

    1. Modelling hydrodynamic dispersion under two-phase flow conditions. (2018). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    2. Parameterization of element balance formulation in reactive compositional flow and transport. (2018). (Masterarbeit). Department of Geoscience & Engineering, Department of Geoscience & Engineering, TU Delft, TU Delft.
    3. Investigating turbulence in an indirect thermo-chemical heat storage reactor. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    4. Experimentelle Visualisierung von Konvektion durch in Wasser gelöstes CO2. (2018). Universität Stuttgart.
    5. Upscaling von kapillaren Netzwerkstrukturen. (2018). (Masterthesis).
    6. Modeling fractures in a CaO/Ca(OH)2 thermo-chemical heat storage reactor. (2018). (Masterthesis).
    7. Machbarkeit und Effizienz von Pumpspeicherung im Untergrund. (2018). (Studienarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    8. Parametersensitivitätsstudie für ein biogeochemisches Goldkreislaufmodell. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    9. Analyse der Möglichkeiten von Energiespeicherung durch Unterwasserdruckluftspeicherkraftwerke. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    10. Analyse der Möglichkeiten von Energiespeicherung durch Windkraftanlagenpumpspeicherkraftwerke. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    11. Implementation of a finite element discretization for Stokes problems in DuMux. (2018). (Propaedeuticum).
    12. Thermodynamische Analyse einer CAES-Anlage - mit Fokus auf analytischer Approximation. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    13. Dichtegetriebene Strömung durch Einlösen von CO2 in Wasser. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    14. Numerical simulations of underground carbon dioxide storage with hydrogen impurities. (2018). (Masterthesis).
    15. Investigation of different coupling schemes for hybrid-dimensional models. (2018). (Masterthesis).
    16. Kopplung zwischen freier Strömung und Strömung im porösen Medium: Modellierung des Transportes von Metallen und Kolloiden in der hyporheischen Zone. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    17. Modelling of salt precipitation and comparison with experimental results. (2018). (Masterthesis).
    18. Modeling heat transfer between porous medium and free flow. (2018). (Projektarbeit).
    19. Investigation of the Streamline-Upwind Petrov-Galerkin method for the Navier-Stokes equations. (2018). (Bachelorarbeit). 0. Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    20. Modellierung und Simulation von Vaskulogenese und Angiogenese. (2018). (Studienarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    21. Pumpversuche zur Bestimmung hydrogeologischer Parameter. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    22. Experimental and numerical investigation of enzymatically induced calcite precipitation in porous media. (2018). (Masterthesis).
    23. Implementation of Adsorption Isotherms in the numerical simulator DuMuX. (2018). (Studienarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    24. Berechnung der Öffnungsweite bei Zugversagen mit Hilfe eines analytischen Ansatzes. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.

  6. 2017

    1. Erstellung eines Programms zur Auslegung von Rohrnetzwerken in der Wasserversorgung. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Institut für Wasser-und Umweltsystemmodellierung Lehrstuhl für Hydromechanik und Hydrosystemmodellierung, Universität Stuttgart.
    2. Lumped parameter models for the human cardiovascular system. (2017). (Masterthesis).
    3. Convergence analysis of two-phase flow systems in porous media: Comparison of implicit hybrid upwinding and phase potential upwinding. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    4. Numerical investigation of turbulent flow around obstacles and evaporating porous media. (2017). (Masterthesis).
    5. Bayesian model selection for hydro-morphodynamic models. (2017). (Masterthesis).
    6. Modellierung des diffusiven Methantransports im Zusammenhang mit Hydraulic Fracturing. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    7. Modellierung und experimentelle Untersuchung des Stoffsystems SrBr2/H2O zur thermochemischen Energiespeicherung. (2017). (Masterthesis).
    8. Simulation of Blood Flow through a Bifurcation at capillary level by 3D and 1D models. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    9. Investigation of the SUPG method: Concept and 1-d implementation. (2017). (Projektarbeit).
    10. Development of a Numerical Model for Microbial Precipitation of Metallic Gold. (2017). (Masterthesis).
    11. Auslegung einer Gebäudeheizung mit einem thermochemischen Wärmespeicher. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    12. Modeling microbially enhanced coal-bed methane production. (2017). (Masterthesis).
    13. Ansätze zur Kopplung von Grundwasser- und Fließgewässermodellen - Vergleich von Softwarelösungen. (2017). (Masterthesis).
    14. Parameterstudie zur Charakterisierung verschiedener Bodenarten für Poren-Netzwerk-Modelle. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    15. Investigation of parametrization of dual-continuum models through multi-scale finite volume methods. (2017). (Masterthesis).
    16. Comparison of the use of hydrogen and methane for underground energy storage. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    17. Entwicklung eines Programms zur Auslegung eines hydraulischen Widders. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    18. Abschätzung von Möglichkeiten der Wärmegewinnung aus Grundwasser und Entwicklung eines Programms für eine Parameterstudie. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    19. Analyse der Möglichkeiten von Energiespeicherung durch Hochhauspumpspeicherkraftwerke. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    20. Modelling of intra- and extracellular flow and transport processes. (2017). (Masterthesis).

  7. 2016

    1. Investigation of a nonlinear Multi-Point Flux Approximation in DuMuX. (2016). (Forschungsmodul).
    2. Untersuchung und Weiterentwicklung der in DuMuX implementierten Flachwassergleichungen. (2016). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    3. Development of 1D and 3D DuMuX models to simulate transport of nano zero-valent iron particles in porous media. (2016). (Masterthesis).
    4. Entwicklung von Kopplungskriterien zur adaptiven Bestimmung des VE-Bereichs in einem gekoppelten Modell. (2016). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    5. Analyse eines modifizierten, vertikal integrierten Modells. (2016). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    6. Development of a numerical model for thermal-ureolysis-induced calcite precipitation. (2016). (Masterthesis).
    7. Modeling the espresso brewing process using a non-isothermal, compositional two-phase approach with dissolution kinetics. (2016). (Masterthesis).
    8. Numerical Simulations to Reproduce Experiments on Capillary Liquid Uptake in Core Samples. (2016). (Masterthesis).
    9. Algorithmus zur Zeitschrittweitenanpassung für das linear elastische Modell. (2016). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    10. Effizienz von Druckluftspeicherung in porösen geologischen Formationen. (2016). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    11. Numerical and experimental investigation of soil-root interactions. (2016). (Masterthesis).
    12. Modellierung des Strömungsübergangs am porösen Medium für Filterelemente. (2016). (Masterthesis).
    13. Development and Evaluation of Iterative Solution Strategies for Coupled Stokes-Darcy Problems. (2016). (Masterthesis).
    14. Experimentelle Untersuchung der effektiven Gaspermeabilität von feinen Schüttungen. (2016). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.

  8. 2015

    1. Fundamentals of multiphase flow in porous media. (2015). (Projektarbeit).
    2. Investigation of an adaptive cell-centerd finite volume scheme with application to soil-root interaction. (2015). (Masterthesis).
    3. Untersuchungen zu Möglichkeiten der Wärmespeicherung bei der adiabaten Druckluftspeicherung. (2015). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    4. Experimentelle Untersuchung der Luftausgasung von Flüssigkeiten. (2015). (Masterthesis).
    5. Development of a model for microbially enhanced coalbed methane. (2015). (Masterthesis).
    6. Steam Assisted Gravity Drainage - Comparison of continuous and cyclic injection on field and laboratory scale. (2015). (Diplomarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    7. Numerische Untersuchung des Einflusses von Heterogenitäten im porösen Medium auf mikrobiell induzierte Kalzitausfällung. (2015). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    8. Pitzer-Ansatz für den reaktiven transport und Vergleich mit dem standard Debey-Hückle-Modell. (2015). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    9. Numerical modeling of salt precipitation around gas wells and its influence on the methane extraction rates. (2015). (Independent-Study).
    10. Entwicklung und Auslegung eines thermischen Frostschutzverfahrens. (2015). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    11. Hierarchical Fracture Modeling Approach. (2015). (Masterthesis).
    12. Domain Decomposition Methods For Partial Differential Equations. (2015). (Seminararbeit).
    13. General theory of three-dimensional consolidation. (2015). (Seminararbeit).
    14. Comparison of different methods for solving elliptic pressure equations in heterogeneous anisotropic porous media. (2015). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    15. Investigation of the influence of hysteresis on underground gas storage. (2015). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    16. Numerical Modeling of Peripheral Arterial Stenoses and Evaluation of Compensation Mechanisms. (2015). (Masterthesis).
    17. Simulating Complex Flow in Karst: Numerical Upscaling through Calibration of a Double Continuum Model. (2015). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    18. Charakterisierung, Auswahl und Untersuchung von Spacern für die Membrandestillation. (2015). (Masterthesis).
    19. Behaviors of air bubbles in drinking water pipelines: Experimental investigation. (2015). (Masterthesis).
    20. Numerical modeling of steam chamber build-up guided by hot-water pre-injection. (2015). (Masterthesis).

  9. 2014

    1. Study on porous medium wall functions for k-epsilon and k-omega turbulence models. (2014). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    2. Spatial model coupling for the simulation of CO2 injection scenarios in deep saline aquifers. (2014). (Masterthesis).
    3. A conceptional approach to the effect of shear failure on the stress field in porous media. (2014). (Masterthesis).
    4. Methane and Ethane sorption on shale. (2014). (Masterthesis).
    5. Kinetic approach to model salt precipitation in porous-media coupled with the free-flow. (2014). (Masterthesis).
    6. Composite Programming als Methode zur Konfliktanalyse. Das Fallbeispiel Polder Waldsee/Altrip/Neuhofen. (2014). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    7. Bürgerbeteiligung als Lösungsweg raumbezogener Konflikte? Eine Analyse am Beispiel der Hochwasserrückhaltung Elzmündung am Oberrhein. (2014). (Bachelorarbeit). Heidelberg, Universität Heidelberg.
    8. Analysis of Processes and Properties at a Porous-Medium Free-Flow Interface with the Application of Evaporation. (2014). (Masterthesis).
    9. Analytical Solution for Determining Brine Leakage Along a Salt Wall. (2014). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    10. Coupling a vascular graph model and the surrounding tissue to simulate flow processes in vascular networks. (2014). (Masterthesis).
    11. Numerical Analysis of Modeling Concepts for Salt Precipitation and Porosity - Permeability Evolution during Brine Evaporation. (2014). (Masterthesis).
    12. Kinetic approach for modeling salt precipitation in porous-media. (2014). (Independent-Study).
    13. Numerical modeling and analysis of groundwater recharge in a wadi system for efficient water management. (2014). (Masterthesis).
    14. Comparison Of Models For Fracture Tips. (2014). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    15. Bayesian networks as decision support tool for inspection and replacement of water distribution systems. (2014). (Masterthesis).
    16. Implementation of advanced algebraic turbulence models on a staggered grid. (2014). (Masterthesis).
    17. Verifikationsproblem mit bekannter Lösung für die Zwei-Phasen-Darcy-Gleichung. (2014). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    18. Wetting properties in porous media: Analysis of the influence on evaporation and radiative heat exchange. (2014). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    19. Investigation of error estimates for cell centered finite volume schemes: analysis and improvement of grid adaptation strategies in DuMuX. (2014). (Masterthesis).
    20. Investigation of a decoupling scheme for modeling reactive transport. (2014). (Masterthesis).
    21. Numerical investigation of microbially induced calcite precipitation at field scale. (2014). (Independent-Study).
    22. Three Phase (Water, Air, and NAPL) Modeling of Bail-Down Test. (2014). (Masterthesis).
    23. Calibration of a complex MODFLOW-based surface water-groundwater model: A case study for the polder IMO. (2014). (Masterthesis).

  10. 2013

    1. Modellierung und Simulation arterieller Netzwerke. (2013). (Masterthesis).
    2. Numerical simulations of geomechanical processes - Verification of a poro-elastic model on the basis of a literature study. (2013). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    3. CO2 as a working fluid in geothermal power plants:Literature review, summary and outlook. (2013). (Studienarbeit). Universität Stuttgart, Institut für Wasserbau.
    4. Modeling water management in PEM fuel cells using Dumux. (2013). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    5. Analytische Berechnung der Jacobimatrix für das nicht-lineare diskrete Gleichungssystem einer Zwei-Phasen-Darcyströmung: Implementierung und Vergleich mit der näherungsweisen Berechnung. (2013). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    6. Modeling Flow and Diffusion along a Salt Flank. (2013). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    7. Coupling of porous-medium and free flow under non-equilibrium conditions. (2013). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    8. Modeling transvascular flow - Analysing the influence of adsorption, degradation and lymph flow. (2013). (Studienarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    9. Comparison of different modelling approaches for reactive transport in porous media. (2013). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    10. Optimizing early-warning monitoring systems for improved drinking water resource protection. (2013). (Masterthesis).
    11. Parameter Study and a Comparison of Different Model Approaches for Simulating the Displacement of Brine and Fracking Fluid Into Overlying Aquifers. (2013). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    12. A comparison of different model reduction techniques for model calibration and risk assessment. (2013). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    13. Einfluss von Grenzschichten auf das Strömungsverhalten. (2013). (Seminararbeit).
    14. Extending a fracture-matrix model towards Forchheimer flow in the fracture network. (2013). (Independent-Study).
    15. Implementation of Element Velocities in a pressure Model for Fractured Porous Media. (2013). (Independent-Study).
    16. Flow Modelling of Coupled Fracture-Matrix Porous Media Systems with a Two Mesh Concept. (2013). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    17. Comparison of Monolithic and Iterative Solvers for Coupled Fracture-Network Rock-Matrix Porous Media Problems. (2013). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    18. Modeling transvascular exchanges of therapeutic agents - Sensitivity analysis. (2013). (Studienarbeit). Universität Stuttgart, Institut für Wasserbau.
    19. Quantitative Risikoabschätzung und Risikomanagement in einem Grundwassereinzugsgebiet am Beispiel Burgberg. (2013). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    20. Analysis of modeling concepts for radiative heat exchange during evaporation processes from porous media. (2013). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    21. Investigating the influence of relative permeability on DNAPL dissolution and depletion at contaminated sites. (2013). (Masterthesis).
    22. Rechenzeitoptimierung bei numerischen Sicherheitsabschätzungen für Atommüll-Endlager. (2013). (Diplomarbeit). Baden/Schweiz, AGU.
    23. Stochastic Investigation of the Thermal Behavior of Lithium-Ion Batteries. (2013). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    24. Impact of transient flow considerations on probabilistic well-head protection delineation. (2013). (Masterthesis).

  11. 2012

    1. A Response Surface Bootstrap Filter To Calibrate CO2 Injection Models. (2012). (Diplomarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    2. Numerical analysis of the influence of turbulence on exchange processes between porous-medium and free flow. (2012). (Diplomarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    3. Untersuchung strömungsmechanischer und thermischer Vorgänge innerhalb des Absorberrohrs eines salzbasierten Parabolrinnenkraftwerks. (2012). (Diplomarbeit). Stuttgart, DLR Deutsches Zentrum für Luft- und Raumfahrt.
    4. Inspecting endovascular aneurysm treatments with porous medium flow simulations and the use of a statistical framework. (2012). (Diplomarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    5. Flow in unsaturated porous media: Numerical and experimental evaluation of the two-phase model and the Richards equation. (2012). (Masterthesis).
    6. The influence of different geological layers and in-situ stress states on the geomechanical processes during CO2 storage. (2012). (Diplomarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    7. Modellierung und experimentelle Untersuchung der Permeabilität von Pulverschüttungen. (2012). (Diplomarbeit). Stuttgart, DLR Deutsches Zentrum für Luft- und Raumfahrt.
    8. Experimental Investigations of Water Infiltration into Unsaturated Soil - Analysis of Dynamic Capillarity Effects. (2012). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    9. Numerical simulation of CO2-leakage scenarios on a large scale under realistic geologic conditions. (2012). (Diplomarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    10. Investigation of the influences of different refinement approaches in the modelling of multiphase flow in porous media. (2012). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    11. Efficient History Matching for Reduced Reservoir Models with PCE-based Bootstrap Filters. (2012). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    12. A Lagrangian Smoothed Particle Framework to Simulate DNAPL Dissolution Pheomena in Subsurface Porous Media. (2012). (Masterthesis).
    13. Coupling of Free Flow and Flow in Porous Media - Dimensional Analysis and Numerical Investigation. (2012). (Masterthesis).
    14. Forchheimer porous-media flow models - Numerical investigation and comparison with experimental data. (2012). (Masterthesis).

  12. 2011

    1. Numerical reduction and numerical simulation of transport processes in blood vessels with bifurcations. (2011). (Diplomarbeit). TU München, Lehrstuhl für Numerische Mathematik.
    2. Modelling biofilm induced calcite precipitation and its effect on two phase flow in porous media. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    3. Untersuchung und Simulationen zum Strömungs- und Verweilzeitverhalten eines Zwischenbehälters in der Wasserversorgung. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.
    4. Implementation of a Reactive Multi-Component Transport Model for the Lime-Carbonic Acid Balance in Dumux. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    5. Simulation der Konvektionsströmung bei der Speicherung von CO2 in tiefen Gesteinsformationen. (2011). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    6. Vereinfachte Methoden zur Flutwellenabschätzung. (2011). (Bachelorarbeit). Universität Stuttgart, Institut für Wasserbau.
    7. Dimensionless Analysis of Convection Enhanced Drug Delivery to Brain Tissues. (2011). (Masterthesis).
    8. Gefährdungsanalyse und Risikoabschätzung zum Schutz von Trinkwasservorkommen am Beispiel Burgberg. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Siedlungswasserbau, Wassergüte- und Abfallwirtschaft.
    9. Risikoanalyse für Wasserschutzgebiete am Beispiel Burgberg. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    10. Optimization of a Calibration Method for Heterogeneous Groundwater Models. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    11. Two phase flow in homogeneous porous media - The role of dynamic capillary pressure in modeling gravity driven fingering. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    12. Adaptive grid refinement for two phase flow in porous media. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    13. Coupling of Free Flow and Flow in Porous Media - A Dimensional Analysis. (2011). (Independent-Study).
    14. Investigation on changing pressures in a saline aquifer before CO2-injection. (2011). (Studienarbeit). Universität Stuttgart, Institut für Wasserbau.
    15. Optimaler Einsatz von Rechenleistung bei alternativen Modellvereinfachungen am Beispiel eines Grundwassermodells. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    16. Theoretisch-numerische Arbeit zum Thema Verdampfung in Mikrokanälen. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    17. Horizontal Redistribution of Two Fluid Phases in a Porous Medium - Experimental and Numerical Investigations. (2011). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.

  13. 2010

    1. Modellierung des Transports von Ölteppichen in Seen am Beispiel des Bodensees. (2010). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    2. Modeling of infiltration processes in the unsaturated zone - switching of boundary condition from Neumann to Dirichlet -. (2010). (Independent-Study).
    3. Stochastic multi-scale simulation of porous media flow with Polynomial Chaos Expansion. (2010). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    4. Parameter Estimation by Ensemble Kalman Filters with Transformed Data. (2010). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    5. Modelling biofilm distribution and its effect on two-phase flow in porous media. (2010). (Studienarbeit). Universität Stuttgart, Institut für Wasserbau.
    6. Cyclic Steam Injection into the Subsurface - solarthermal steam generation for enhanced oil recovery. (2010). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.

  14. 2009

    1. Modeling Convection-Enhanced Delivery into Brain Tissue using Information from Magnetic Resonance Imaging. (2009). (Masterthesis).
    2. Numerical solution of Philip’s redistribution problem. (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    3. Modellierung des Abwassernetzes der Oase Beni Abbes, Algerien. (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    4. Examination of the assumption of thermal equilibrium on the fluid distribution and front stability. (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    5. CO2 sequestration simulations: A comparison study between DuMuX and Eclipse. (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    6. Two-phase flow modeling in porous media with kinetic interphase mass transfer processes in fractures. (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    7. Determination of Interfacial Area - Capillary Pressure - Saturation Relationships for a Single Fracture: Study, Upscaling, and Determination. (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    8. Modelling Carbon Dioxide Flow in the Shallow Subsurface. (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    9. Modeling the transfer of therapeutic agents from the vascular space to the tissue compartment (a continuum approach). (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    10. Numerical modeling of enhanced gas recovery with CO2 storage - Primary variable switch -. (2009). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.

  15. 2008

    1. Implementation and Application of a Hysteresis Model for Multiphase Flow and Transport in Porous Media. (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    2. Towards a model concept for coupling porous gas diffusion layer and gas distributor in PEM fuel cells. (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    3. Weiterentwicklung einer Finite-Volumen-Methode für die Flachwassergleichungen zur Simulation des Oberflächenabflusses im Gewässer und im Gelände. (2008). (Diplomarbeit). Technische Universität Berlin, Institut für Bauingenieurwesen.
    4. Modeling the Spatial and Temporal Distribution of Therapeutic Agents in Tumor Tissue (a Continuum Approach). (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    5. A double-continuum approach for two-phase flow in macroporous media: Parameter study and applications. (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    6. Contaminant Transport in Lake Constance: Analysis of Moments and the Dilution Index. (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    7. Numerical Simulations of CO2 Injection into Saline Aquifers: Estimation of Storage Capacity and Arrival Times using Multiple Realizations of Heterogeneous Permeability Fields. (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    8. Comparison of mathematical and numerical models for twophase flow in porous media. (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    9. The use of natural heat as a tracer to quantify groundwater surface water interactions: Maules Creek, New South Wales, Australia. (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    10. Beschreibung und Quantifizierung der Wechselwirkungen zwischen Grundwasserkörper, Baggersee und Drainagegräben im Rahmen einer 3D Strömungs- und Transportmodellierung. (2008). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.

  16. 2007

    1. Implementation of a Stochastic Wind Model into the Virtual WaterWay (VWW) Program. (2007). (Masterthesis).
    2. Saturation Determination for Multiphase Systems in Porous Medium Using Light Transmission Method. (2007). (Independent-Study).
    3. Numerical Investigations of Flow through Fractured Porous Media. (2007). (Masterthesis).
    4. Simulation der Wasserqualität im Bodensee mit Hilfe eines dreidimensionalen Modells. (2007). (Diplomarbeit). Stuttgart, Institut für Wasserbau, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    5. CO2 Storage into Dipped Saline Aquifers Including Ambient Water Flow. (2007). (Diplomarbeit). Stuttgart, Institut für Wasserbau.
    6. The development of a single phase multicomponent model with sorption for the analysis of methane migration from subsurface coal seams. (2007). (Masterthesis).
    7. Investigations on Flow Processes in Absorbent Products using FeFlow Finite Element Software. (2007). (Diplomarbeit). Schwalbach am Taunus, Procter & Gamble GmbH.
    8. Investigations of Carbon Dioxide Storage Capacity in Saline Aquifers. (2007). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    9. Erarbeitung und Implementierung eines Modellkonzepts zur Simulation von Strömungs- und Transportprozessen im menschlichen Gehirn. (2007). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    10. Characterisation of tracer distribution in a lake using spatial moments. (2007). (Independent-Study).
    11. Characterisation of tracer distribution in Upper Lake Constance using spatial moments. (2007). (Studienarbeit). Stuttgart, Institut für Wasserbau.
    12. The influende on mixing in a lake of an internal boundary layer for the wind. (2007). (Independent-Study).
    13. Stochastische Modellierung und hydrogeologische Charakterisierung von Karstgrundwasserleitern. (2007). (Diplomarbeit). Stuttgart, Institut für Wasserbau, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.

  17. 2006

    1. Numerical study on solute mixing in thermally induced buoyancy flow in groundwater. (2006). (Masterthesis).
    2. Efficient Spectral Methods for Geostatistical Interpolation. (2006). (Diplomarbeit). Stuttgart, Institut für Wasserbau.
    3. Investigation on macrodispersion for two-phase flow in heterogeneous porous media. (2006). (Masterthesis).
    4. Prinzipstudie zur CO2-Migration im Untergrund in Bezug auf die Mineralwässer Stuttgarts. (2006). (Diplomarbeit). Stuttgart, Institut für Wasserbau, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    5. Modeling of CO2 Sequestration: Carbon Dioxide Entry Behaviour at the Cap Rock. (2006). (Studienarbeit). Universität Stuttgart, Institut für Wasserbau.

  18. 2005

    1. Entwicklung und Implementierung eines numerischen Modellkonzepts zur Simulation von Alkoholspülungsprozessen in DNAPL-kontaminierten Grundwasserleitern. (2005). (Diplomarbeit). Stuttgart, Institut für Wasserbau.
    2. Experimental and numerical investigations on steam injection in saturated soils. (2005). (Masterthesis).
    3. Modelling of Multiphase Multicomponent Flow and Transport in Heap Leaching of Copper Ores. (2005). (Masterthesis).
    4. Identification of a REV for a given upscaling method. (2005). (Masterthesis).
    5. Sensitivity Analysis of flow and fracture parameters in fractured porous medium. (2005). (Masterthesis).
    6. Physical Aspects in the Numerical Modeling of Carbon-Dioxide Sequestration. (2005). (Masterthesis).
    7. Using the moving mesh feature to simulate the unsteady electrostatic spray painting produced by a high-speed rotary bell atomizer with the external charge. (2005). (Masterthesis).
    8. Thermal Effects of Carbon Dioxide Sequestration in the Subsurface. (2005). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    9. Einfluss von Heterogenitäten auf Mehrphasenströmungen. (2005). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    10. Numerical Modeling of Methane Adsorption and Transport Processes in Mined Areas. (2005). (Masterthesis).
    11. Untersuchung von Randbedingungen bei der numerischen Simulation von Zweiphasenströmungen in porösen Medien. (2005). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.

  19. 2004

    1. Inverse modeling of groundwater transport using temporal moments of concentration. (2004). (Masterthesis).
    2. Simultaneous geostatistical identification of conductivity and recharge parameters in the groundwater flow equation. (2004). (Masterthesis).
    3. Steam- and steam-air-injection in the saturated zone: experimental and numerical investigations on DNAPL-mobilization and heat front behaviour. (2004). (Masterthesis).
    4. Parameter study for the migration of DNAPL around a sand lens. (2004). (Independent-Study).
    5. Effects of groundwater density on CO2 migration in the subsurface. (2004). (Independent-Study).
    6. Modeling of Mine Gas Repositories. (2004). (Masterthesis).
    7. Interpretation of simulation results including a dynamic capillary pressure relationship. (2004). (Masterthesis).
    8. Parametrisierung von Buhnen in 2D-HN-Modellen anhand numerischer Modellrechnungen und Naturdaten der Donau. (2004). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
    9. The Influence of the Intrinsic Permeability and the van Genuchten Parameters on Small-Scale Simulation Results. (2004). (Masterthesis).
    10. Evaluation of CO2 velocity changes in a CO2 plume migrating in the subsurface. (2004). (Independent-Study).
    11. Modeling of CO2 Injection in Geological Formations: The Effect of Dissolved CO2 on Water Density. (2004). (Independent-Study).
    12. Development of a Finite Element model for a cylindrical device for the determination of the hydraulic conductivity tensor. (2004). (Masterthesis).

  20. 2003

    1. Artificial Groundwater Recharge. (2003). (Independent-Study).
    2. Experimental determination of transverse dispersion coefficients in porous media. (2003). (Masterthesis).
    3. Simultaneous Identification of Conductivity and Recharge Parameters in the Groundwater Flow Equation. (2003). (Independent-Study).

  21. 2002

    1. Untersuchungen zur Sanierungseffizienz und zum Strömungsverhalten bei Sattdampfinjektion in organisch kontaminierten natürlichen Boden eines industriellen Standortes. (2002). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    2. Modellierung des reaktiven Transports von Uran im Kontext einer biotechnischen in-situ Sanierung. (2002). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.

  22. 2001

    1. Effiziente Algorithmenm für zirkuläre Matritzen und Block-Zirkuläre Matritzen mir zirkulären Blöcken. (2001). (Studienarbeit). Universität Stuttgart, Institut für Wasserbau.
    2. The alternating Schwarz method: mathematical foundation and parallel implementation. (2001). (Masterthesis).

  23. 2000

    1. Age determination of a TCE source zone using solute transport profiles in an underlying clayey aquitard. (2000). (Diplomarbeit). Waterloo, Canada, Department of Earth Sciences.

  24. 1998

    1. Structure of Phosphorus Transport in Lake Yanaka in Relation to Eutrophication. (1998). (Masterthesis).

  25. 1997

    1. Entwicklung eines thermisch unterstützten in-situ Sanierungsverfahrens: Experimentelle Untersuchung zur nicht-isothermen Dreiphasenströmung im technischen Maßstab. (1997). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.

  26. 1996

    1. Experimentelle Untersuchung bei nicht-isothermer Mehrphasenströmung durch ein definiert heterogenes, poröses Medium. (1996). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.
    2. Experimentelle Parameteranalyse einer eindimensionalen, nicht-isothermen Mehrphasenströmung durch ein poröses Medium. (1996). (Diplomarbeit). Universität Stuttgart, Institut für Mechanische Verfahrenstechnik.

  27. 1995

    1. Experimentelle Untersuchungen des Einflusses der Permeabilität und der Schadstoffeigenschaften bei eindimensionaler nicht-isothermer Mehrphasenströmung durch ein poröses Medium. (1995). (Diplomarbeit). Universität Stuttgart, Institut für Wasserbau.

Kontakt

Dieses Bild zeigt Lehrstuhl für Hydromechanik und Hydrosystem-modellierung

Lehrstuhl für Hydromechanik und Hydrosystem-modellierung

 
 

Anfahrt

Pfaffenwaldring 61, 70569 Stuttgart

Zum Seitenanfang