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Coltman, Edward

Edward Coltman

Herr M.Sc.

wissenschaftlicher Mitarbeiter
Institut für Wasser- und Umweltsystemmodellierung
Lehrstuhl für Hydromechanik und Hydrosystemmodellierung

Kontakt

+49 711 685 64729
+4971168560430
E-Mail
Visitenkarte (VCF)

Pfaffenwaldring 61
70569 Stuttgart
Deutschland
Raum: 1.008

Sprechstunde

Nach Vereinbarung

Lebenslauf

High School Degree

Mai 2009 in Reading, MA (USA)

Akademische Grade

2013: B.Sc. im Bauingenieurwesen, Tufts University, Medford, MA (USA)
2017: M.Sc. in Water Resources Engineering and Management, Universität Stuttgart (Germany)

Sanierungsingenieur

September 2015 in Chelmsford MA (USA)

Akademischer Werdegang

Seit Februar 2018: Doktorand, Institut für Wasser- und Umweltsystemmodellierung, Universität Stuttgart

Publikationen

(Zeitschriften-) Aufsätze
1. 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), Article 7. https://doi.org/10.1029/2021WR029578
  Zusammenfassung
  Abstract Accurately predicting bare-soil evaporation requires the proper characterization of the near-surface atmospheric conditions. These conditions, dependent on factors such as surface microtopography and wind velocity, vary greatly and therefore require high-resolution datasets to be fully incorporated into evaporation models. These factors are oftentimes parameterized in models through the aerodynamic resistance (ra), in which the vapor roughness length (z0v) and the momentum roughness length (z0m) are two crucial parameters that describe the transport near the soil-atmosphere interface. Typically, when evaluating bare-soil evaporation, these two characteristic lengths are assumed equal, although differences are likely to occur especially in turbulent flows over undulating surfaces. Thus, this study aims to investigate the relationship between z0v and z0m above undulating surfaces to ultimately improve accuracy in estimating evaporation rate. To achieve this goal, four uniquely designed wind tunnel—soil tank experiments were conducted considering different wind speeds and undulation spacings. Particle image velocimetry (PIV) was used to measure the velocity field above the undulating surface in high resolution. Using the high-fidelity data set, the logarithmic ratio of z0v to z0m is determined and used to estimate ra. Results confirm that these lengths differ significantly, with the logarithmic ratio roughly ranging from −15 to −5 under the conditions tested. PIV-measured results demonstrate this ratio is closely tied to the mass and momentum transport behaviors influenced by surface undulations. Using the data-integrated formulation of ra, predictions of evaporation rate were prepared for both the laboratory and lysimeter experiments, demonstrating the efficacy of the proposed approach in this study.
  BibTeX
  @article{gao2021a, abstract = {Abstract Accurately predicting bare-soil evaporation requires the proper characterization of the near-surface atmospheric conditions. These conditions, dependent on factors such as surface microtopography and wind velocity, vary greatly and therefore require high-resolution datasets to be fully incorporated into evaporation models. These factors are oftentimes parameterized in models through the aerodynamic resistance (ra), in which the vapor roughness length (z0v) and the momentum roughness length (z0m) are two crucial parameters that describe the transport near the soil-atmosphere interface. Typically, when evaluating bare-soil evaporation, these two characteristic lengths are assumed equal, although differences are likely to occur especially in turbulent flows over undulating surfaces. Thus, this study aims to investigate the relationship between z0v and z0m above undulating surfaces to ultimately improve accuracy in estimating evaporation rate. To achieve this goal, four uniquely designed wind tunnel—soil tank experiments were conducted considering different wind speeds and undulation spacings. Particle image velocimetry (PIV) was used to measure the velocity field above the undulating surface in high resolution. Using the high-fidelity data set, the logarithmic ratio of z0v to z0m is determined and used to estimate ra. Results confirm that these lengths differ significantly, with the logarithmic ratio roughly ranging from −15 to −5 under the conditions tested. PIV-measured results demonstrate this ratio is closely tied to the mass and momentum transport behaviors influenced by surface undulations. Using the data-integrated formulation of ra, predictions of evaporation rate were prepared for both the laboratory and lysimeter experiments, demonstrating the efficacy of the proposed approach in this study.}, author = {Gao, Bo and Coltman, Edward and Farnsworth, John and Helmig, Rainer and Smits, Kathleen M.}, doi = {10.1029/2021WR029578}, eprint = {https://agupubs.onlinelibrary.wiley.com/doi/pdf/10.1029/2021WR029578}, journal = {Water Resources Research}, month = {06}, number = 7, pages = {e2021WR029578}, title = {Determination of Vapor and Momentum Roughness Lengths Above an Undulating Soil Surface Based on PIV-Measured Velocity Profiles}, url = {https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2021WR029578}, volume = 57, year = 2021 }
  Link
  https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2021WR029578
2. Heck, K., Coltman, E., Schneider, J., & Helmig, R. (2020). Influence of Radiation on Evaporation Rates: A Numerical Analysis. Water Resources Research, 56(10), Article 10. https://doi.org/10.1029/2020WR027332
  - BibTeX
  - Link
  BibTeX
  @article{lh2-2020-heck-evaporation, author = {Heck, K. and Coltman, E. and Schneider, J. and Helmig, R.}, doi = {10.1029/2020WR027332}, eprint = {https://agupubs.onlinelibrary.wiley.com/doi/pdf/10.1029/2020WR027332}, journal = {Water Resources Research}, month = {10}, note = {e2020WR027332 10.1029/2020WR027332}, number = 10, pages = {e2020WR027332}, publisher = {American Geophysical Union ({AGU})}, title = {Influence of Radiation on Evaporation Rates: A Numerical Analysis}, url = {https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2020WR027332}, volume = 56, year = 2020 }
  Link
  https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2020WR027332
3. 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), Article 2. https://doi.org/10.1007/s11242-020-01445-6
  - BibTeX
  - Link
  BibTeX
  @article{lh2-2020-coltman-turbulence, author = {Coltman, E. and Lipp, M. and Vescovini, A. and Helmig, R.}, doi = {10.1007/s11242-020-01445-6}, journal = {Transport in porous media}, month = {07}, number = 2, pages = {275--301}, publisher = {Springer Science and Business Media {LLC}}, title = {Obstacles, Interfacial Forms, and Turbulence: A Numerical Analysis of Soil-Water Evaporation Across Different Interfaces}, url = {https://doi.org/10.1007/s11242-020-01445-6}, volume = 134, year = 2020 }
  Link
  https://doi.org/10.1007/s11242-020-01445-6
4. 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), Article 9. https://doi.org/10.1029/2020WR027600
  - BibTeX
  - Link
  BibTeX
  @article{lh2-2020-heck-gas-component-transport, author = {Bahlmann, L. M. and Smits, K. M. and Heck, K. and Coltman, E. and Helmig, R. and Neuweiler, I.}, doi = {10.1029/2020WR027600}, eprint = {https://agupubs.onlinelibrary.wiley.com/doi/pdf/10.1029/2020WR027600}, journal = {Water Resources Research}, month = {09}, note = {e2020WR027600 10.1029/2020WR027600}, number = 9, pages = {e2020WR027600}, publisher = {American Geophysical Union ({AGU})}, title = {Gas Component Transport Across the Soil-Atmosphere Interface for Gases of Different Density: Experiments and Modeling}, url = {https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2020WR027600}, volume = 56, year = 2020 }
  Link
  https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2020WR027600
5. 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
  - BibTeX
  BibTeX
  @article{NULL, author = {Yang, Guang and Coltman, Edward and Weishaupt, Kilian and Terzis, Alexandros and Helmig, Rainer and Weigand, Bernhard}, doi = {10.1007/s11242-019-01255-5}, journal = {Transport in Porous Media}, month = {02}, note = {, IWS2ID=4510 , Partnerinstitution: Institut für Thermodynamik der Luft- und Raumfahrt (ITLR) , Partneraddress: Stuttgart }, title = {On the Beavers-Joseph interface condition for non-parallel coupled channel flow over a porous structure at high Reynolds numbers}, year = 2019 }
6. 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
  - BibTeX
  BibTeX
  @article{koch2018dumux, author = {Koch, Timo and Gläser, Dennis and Weishaupt, Kilian and Ackermann, Sina and Beck, Martin and Becker, Beatrix and Burbulla, S. and Class, Holger and Coltman, Edward and Fetzer, Thomas and Flemisch, Bernd and Grüninger, Christoph and Heck, Katharina and Hommel, Johannes and Kurz, Theresa and Lipp, Melanie and Mohammadi, Farid and Schneider, Martin and Seitz, Gabriele and Scholz, Simon and Weinhardt, Felix}, doi = {10.5281/zenodo.2479595}, title = {DuMuX 3.0.0}, year = 2018 }
7. 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
  - BibTeX
  - Link
  BibTeX
  @article{NULL, author = {Hommel, Johannes and Coltman, Edward and Class, Holger}, doi = {10.1007/s11242-018-1086-2}, journal = {Transport in Porous Media}, month = {05}, note = {, IWS2ID=4501 }, number = 124, page = {589-629}, title = {Porosity-Permeability Relations for Evolving Pore Space: A Review with a Focus on (Bio-)geochemically Altered Porous Media}, url = {https://link.springer.com/article/10.1007%2Fs11242-018-1086-2}, volume = 2, year = 2018 }
  Link
  https://link.springer.com/article/10.1007%2Fs11242-018-1086-2
Abschlussarbeiten
1. Coltman, E. (2017). Numerical investigation of turbulent flow around obstacles and evaporating porous media [Masterthesis].
  - BibTeX
  BibTeX
  @mastersthesis{NULL, author = {Coltman, Edward}, month = {11}, note = {, IWS2ID=4492 , Institution: Institut für Wasser- und Umweltsystemmodellierung , Address: Universität Stuttgart }, school = {Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung}, title = {Numerical investigation of turbulent flow around obstacles and evaporating porous media}, type = {Masterthesis}, year = 2017 }

Poster

Helmig, R., Coltman, E., Fetzer, T., & Heck, K. (2018). Coupling free and porous-media flow. In Gordon Research Conference on Flow and Transport in Permeable Media, 08.07.2018 - 13.07.2018, Newry, ME, USA.
- BibTeX
BibTeX
@misc{NULL, author = {Helmig, Rainer and Coltman, Edward and Fetzer, Thomas and Heck, Katharina}, booktitle = {Gordon Research Conference on Flow and Transport in Permeable Media, 08.07.2018 - 13.07.2018, Newry, ME, USA}, month = {07}, note = {, date=09.07.2018, IWS2ID=4523 }, title = {Coupling free and porous-media flow}, type = {Poster}, year = 2018 }

betreute studentische Arbeiten

Coupled Turbulent Free- and Porous Media Flows: Investigations of Interfacial Roughness. (2022). (mastersthesis).
Coupled Free-Flow and Porous Media Flow Systems: Analysis of Turbulent Free-Flow Condtions and Pore-Network Models. (2022). (Forschungsmodul2).
Averaged Analysis of Pore Scale Dynamics via Closure Problems. (2021). (Forschungsmodul 2).
Modelling Turbulence in Coupled Environments: The K-Shear Stress Transport Model. (2021). (Master’s Thesis).
Combination of a locally-refined quadtree finite-volume staggered grid scheme for the Navier-Stokes equation with turbulence models. (2020). (Forschungsmodul 2).
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
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.
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.
Investigating turbulence in an indirect thermo-chemical heat storage reactor. (2018). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.

Aktuelle Forschungsprojekte

EXC 2075, PN 1-5: Dispersion concept for interface closures in the context of coupling free-flow and porous-media multiphase flow on the REV scale
Laufzeit: 01/2020 - 06/2023
Abteilung: LH2
Leitung: Rainer Helmig, Martin Schneider
Finanzierung: DFG

Promotionsvorhaben im Rahmen der Graduiertenschule des SFB 1313 (IRTG-IMPM)

Exchange Processes at the Soil-Atmosphere Interface: Modelling and Numerical Analysis
Betreuer: Rainer Helmig

Edward Coltman

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betreute studentische Arbeiten

Aktuelle Forschungsprojekte

Promotionsvorhaben im Rahmen der Graduiertenschule des SFB 1313 (IRTG-IMPM)

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