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Heck, Katharina

Katharina Heck

Dr.-Ing.

Academic Staff
Institute for Modelling Hydraulic and Environmental Systems
Department of Hydromechanics and Modelling of Hydrosystems

Contact

+49 711 685 64719
+49 711 685 54719
Email
Business card (VCF)

Pfaffenwaldring 61
70569 Stuttgart
Germany
Room: 1.007

Office Hours

By appointment only

Vita

Abitur

June 2010 in Kirchheim/Teck (Germany)

Academic Degrees

2013: Bachelor of Science in Geoecology, Karlsruhe Institute of Technology (KIT) (Germany)
2016: Master of Science in Environmental Engineering, University of Stuttgart (Germany)
2020: Defense of Doctoral Thesis, University of Stuttgart (Germany)

Academic Career

2016-2020: Doctoral Researcher within SFB 1313, Institute for Modelling Hydraulic and Environmental Systems, University of Stuttgart (Germany)
since 2021: Postdoctoral Researcher within SFB 1313, Institute for Modelling Hydraulic and Environmental Systems, University of Stuttgart (Germany)

Offices in the Academic Administration

Member of the SFB 1313 Management Team

publications

(Journal-) Articles
1. 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
  Abstract
  The exchange of gas components across the subsurface/atmosphere interface influences multiphase flow and reactive transport in the subsurface and is crucial for many biogeochemical processes, for the emission of greenhouse gases, and for the fate of volatile contaminants. In this study, we present a modeling approach to simulate non-isothermal multiphase flow and multicomponent reactive transport in coupled subsurface/atmosphere compartments. The model is based on a coupled porous medium/free flow domain in which the Navier-Stokes equation is used to describe single-phase (gaseous) flow in the free-flow subdomain and Darcy's law is applied for two-phase flow in the porous medium subdomain (i.e., two-domain approach). The implementation is performed by coupling COMSOL Multiphysics and PhreeqcRM, which enables the investigation of the interplay between multi-physical processes (i.e., flow, mass and heat transport) in the coupled compartments and geochemical reactions in the porous medium. We first present a set of benchmark examples in which key features of the proposed model are tested against other numerical simulators and an analytical solution. Successively, we take advantage of the unique capabilities of the proposed approach to explore conservative and reactive transport of gas components in a coupled porous medium/free flow domain. The results show that the exchange processes between the compartments control the location of reactive zones and the extent of geochemical reactions (i.e., mineral dissolution) by changing the spatiotemporal distribution of fluid phases and enhancing the interphase mass transfer of key gas components such as oxygen and carbon dioxide.
  BibTeX
  @article{lh2-dtu-ahmadi-2022, abstract = {The exchange of gas components across the subsurface/atmosphere interface influences multiphase flow and reactive transport in the subsurface and is crucial for many biogeochemical processes, for the emission of greenhouse gases, and for the fate of volatile contaminants. In this study, we present a modeling approach to simulate non-isothermal multiphase flow and multicomponent reactive transport in coupled subsurface/atmosphere compartments. The model is based on a coupled porous medium/free flow domain in which the Navier-Stokes equation is used to describe single-phase (gaseous) flow in the free-flow subdomain and Darcy's law is applied for two-phase flow in the porous medium subdomain (i.e., two-domain approach). The implementation is performed by coupling COMSOL Multiphysics and PhreeqcRM, which enables the investigation of the interplay between multi-physical processes (i.e., flow, mass and heat transport) in the coupled compartments and geochemical reactions in the porous medium. We first present a set of benchmark examples in which key features of the proposed model are tested against other numerical simulators and an analytical solution. Successively, we take advantage of the unique capabilities of the proposed approach to explore conservative and reactive transport of gas components in a coupled porous medium/free flow domain. The results show that the exchange processes between the compartments control the location of reactive zones and the extent of geochemical reactions (i.e., mineral dissolution) by changing the spatiotemporal distribution of fluid phases and enhancing the interphase mass transfer of key gas components such as oxygen and carbon dioxide.}, author = {Ahmadi, Navid and Muniruzzaman, Muhammad and Sprocati, Riccardo and Heck, Katharina and Mosthaf, Klaus and Rolle, Massimo}, doi = {https://doi.org/10.1016/j.advwatres.2022.104303}, issn = {0309-1708}, journal = {Advances in Water Resources}, pages = 104303, title = {Coupling soil/atmosphere interactions and geochemical processes: A multiphase and multicomponent reactive transport approach}, url = {https://www.sciencedirect.com/science/article/pii/S0309170822001671}, volume = 169, year = 2022 }
  Link
  https://www.sciencedirect.com/science/article/pii/S0309170822001671
2. 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
  Abstract
  We present version 3 of the open-source simulator for flow and transport processes in porous media DuMux. DuMux is based on the modular C++ framework Dune (Distributed and Unified Numerics Environment) and is developed as a research code with a focus on modularity and reusability. We describe recent efforts in improving the transparency and efficiency of the development process and community-building, as well as efforts towards quality assurance and reproducible research. In addition to a major redesign of many simulation components in order to facilitate setting up complex simulations in DuMux, version 3 introduces a more consistent abstraction of finite volume schemes. Finally, the new framework for multi-domain simulations is described, and three numerical examples demonstrate its flexibility.
  BibTeX
  @article{Version3Dumux, abstract = {We present version 3 of the open-source simulator for flow and transport processes in porous media DuMux. DuMux is based on the modular C++ framework Dune (Distributed and Unified Numerics Environment) and is developed as a research code with a focus on modularity and reusability. We describe recent efforts in improving the transparency and efficiency of the development process and community-building, as well as efforts towards quality assurance and reproducible research. In addition to a major redesign of many simulation components in order to facilitate setting up complex simulations in DuMux, version 3 introduces a more consistent abstraction of finite volume schemes. Finally, the new framework for multi-domain simulations is described, and three numerical examples demonstrate its flexibility.}, author = {Koch, Timo and Gl\"{a}ser, Dennis and Weishaupt, Kilian and Ackermann, Sina and Beck, Martin and Becker, Beatrix and Burbulla, Samuel and Class, Holger and Coltman, Edward and Emmert, Simon and Fetzer, Thomas and Gr\"{u}ninger, Christoph and Heck, Katharina and Hommel, Johannes and Kurz, Theresa and Lipp, Melanie and Mohammadi, Farid and Scherrer, Samuel and Schneider, Martin and Seitz, Gabriele and Stadler, Leopold and Utz, Martin and Weinhardt, Felix and Flemisch, Bernd}, doi = {10.1016/j.camwa.2020.02.012}, issn = {0898-1221}, journal = {Computers {\&} Mathematics with Applications}, month = {01}, publisher = {Elsevier {BV}}, title = {{DuMux} 3 {\textendash} an open-source simulator for solving flow and transport problems in porous media with a focus on model coupling}, url = {https://doi.org/10.1016/j.camwa.2020.02.012}, year = 2021 }
  Link
  https://doi.org/10.1016/j.camwa.2020.02.012
3. 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), Article 5. https://doi.org/10.1007/s10596-021-10057-y
  Abstract
  Multicomponent gas transport in porous media and at the interface between porous media and free flow occurs in a wide range of technical and environmental systems. Modeling tools are required for the quantitative description of such coupled environmental compartments. We present a benchmark study to compare different diffusion models as well as different coupling concepts employed for the description of multicomponent gas flow and transport at the porous medium/free-flow interface. The benchmark problems allowed us to compare two diffusion models (Fickian and Maxwell-Stefan formulations) for predicting the transport behavior of multicomponent mixtures in porous media and in presence of a free flow. The examples highlighted the importance of interaction between different diffusing components by applying the Maxwell-Stefan formulation, as well as the impact of the free flow velocity on gas migration at the interface under diffusion- and advection-dominated conditions. The problems were solved using two simulation tools, incorporating different coupling concepts to describe the physics of flow and transport processes. In COMSOL Multiphysics, we implemented a single-domain Brinkman approach, whereas in the DuMuX simulator we used a two-domain approach with the Navier-Stokes equation for the free flow and Darcy’s law for the porous medium. Also, the formulation of the Maxwell-Stefan equation for multicomponent transport was different between the two codes. Despite the different modeling concepts, mathematical descriptions and numerical schemes implemented in the two simulators, their outcomes demonstrate excellent agreement for all benchmark problems, as well as the capability to reproduce the results of previous modeling and experimental studies.
  BibTeX
  @article{ahmadi_multicomponent_2021, abstract = {Multicomponent gas transport in porous media and at the interface between porous media and free flow occurs in a wide range of technical and environmental systems. Modeling tools are required for the quantitative description of such coupled environmental compartments. We present a benchmark study to compare different diffusion models as well as different coupling concepts employed for the description of multicomponent gas flow and transport at the porous medium/free-flow interface. The benchmark problems allowed us to compare two diffusion models (Fickian and Maxwell-Stefan formulations) for predicting the transport behavior of multicomponent mixtures in porous media and in presence of a free flow. The examples highlighted the importance of interaction between different diffusing components by applying the Maxwell-Stefan formulation, as well as the impact of the free flow velocity on gas migration at the interface under diffusion- and advection-dominated conditions. The problems were solved using two simulation tools, incorporating different coupling concepts to describe the physics of flow and transport processes. In COMSOL Multiphysics, we implemented a single-domain Brinkman approach, whereas in the DuMuX simulator we used a two-domain approach with the Navier-Stokes equation for the free flow and Darcy’s law for the porous medium. Also, the formulation of the Maxwell-Stefan equation for multicomponent transport was different between the two codes. Despite the different modeling concepts, mathematical descriptions and numerical schemes implemented in the two simulators, their outcomes demonstrate excellent agreement for all benchmark problems, as well as the capability to reproduce the results of previous modeling and experimental studies.}, author = {Ahmadi, Navid and Heck, Katharina and Rolle, Massimo and Helmig, Rainer and Mosthaf, Klaus}, doi = {10.1007/s10596-021-10057-y}, issn = {1573-1499}, journal = {Computational Geosciences}, month = {10}, number = 5, pages = {1493--1507}, title = {On multicomponent gas diffusion and coupling concepts for porous media and free flow: a benchmark study}, url = {https://doi.org/10.1007/s10596-021-10057-y}, volume = 25, year = 2021 }
  Link
  https://doi.org/10.1007/s10596-021-10057-y
4. 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
5. 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
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. 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
  - BibTeX
  BibTeX
  @article{NULL, author = {Koch, Timo and Heck, Katharina and Schröder, Natalie and Class, Holger and Helmig, Rainer}, doi = {10.2136/vzj2017.12.0210}, journal = {Vadose Zone Journal}, month = {08}, note = {, IWS2ID=4546 }, title = {A new simulation framework for soil-root interaction, evaporation, root growth, and solute transport}, year = 2018 }
8. 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.
  - BibTeX
  BibTeX
  @article{NULL, author = {Trautz, Andrew and Illangasekare, Tissa and Rodriguez-Iturbe, Ignacio and Heck, Katharina and Helmig, Rainer}, journal = {Water Resources Research}, month = {04}, note = {, IWS2ID=4464 , Partneraddress: Golden, Colorado, USA }, page = {3319-3340}, title = {Development of an experimental approach to study coupled soil-plant-atmosphere processes using plant analogs}, volume = 53, year = 2017 }
Theses
1. Heck, K. (2016). Numerical and experimental investigation of soil-root interactions [Masterthesis].
  - BibTeX
  BibTeX
  @mastersthesis{NULL, author = {Heck, Katharina}, month = {03}, note = {, IWS2ID=4376 , Institution: Institut für Wasser- und Umweltsystemmodellierung , Address: Universität Stuttgart }, school = {Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung}, title = {Numerical and experimental investigation of soil-root interactions}, type = {Masterthesis}, year = 2016 }
PhDs
1. 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 (Vol. 280). https://doi.org/10.18419/opus-11635
  - BibTeX
  - Link
  BibTeX
  @phdthesis{lh2-diss-2021-heck, author = {Heck, Katharina}, doi = {10.18419/opus-11635}, isbn = {978-3-942036-84-9}, month = {07}, publisher = {Eigenverlag des Instituts für Wasser- und Umweltsystemmodellierung der Universität Stuttgart}, school = {Universität Stuttgart, Institut für Wasser- Umweltsystemmodellierung}, series = {Mitteilungsheft}, title = {Modelling and analysis of multicomponent transport at the interface between free- and porous-medium flow - influenced by radiation and roughness}, type = {Promotionsschrift}, url = {https://elib.uni-stuttgart.de/handle/11682/11652}, volume = 280, year = 2021 }
  Link
  https://elib.uni-stuttgart.de/handle/11682/11652

posters

R. Helmig, E. Coltman, T. Fetzer, and K. Heck, “Coupling free and porous-media flow,” Gordon Research Conference on Flow and Transport in Permeable Media, 08.07.2018 - 13.07.2018, Newry, ME, USA. in Gordon Research Conference on Flow and Transport in Permeable Media, 08.07.2018 - 13.07.2018, Newry, ME, USA. Jul. 2018.
- 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 }

supervised student assignements

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.
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.
Numerische Simulation des wärmegekoppelten Stofftransports durch die Speicherhülle eines Erdbeckenspeichers. (2022). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
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.
Untersuchung des lokalen thermischen Nicht-Gleichgewichts bei der thermochemischen Wärmespeicherung. (2020). (Projektarbeit). Universität Stuttgart.
Vergleich von Mehrkomponentendiffusionsansätzen im Kontext der Anwendung auf Brennstoffzellen. (2019). (bachelor thesis).
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.
Modelling of salt precipitation and comparison with experimental results. (2018). (Masterthesis).
Modelling hydrodynamic dispersion under two-phase flow conditions. (2018). (Masterarbeit). Universität Stuttgart, Institut für Wasser-und Umweltsystemmodellierung, Lehrstuhl für Hydromechanik und Hydrosystemmodellierung.
Abschätzung von Möglichkeiten der Wärmegewinnung aus Grundwasser und Entwicklung eines Programms für eine Parameterstudie. (2017). (Bachelorarbeit). Universität Stuttgart, Institut für Wasser- und Umweltsystemmodellierung.

Current research projects

SFB 1313, A02: Advanced modelling concepts for coupling free flow with porous-media flow
Duration: 01/2018 - 12/2025
Departments: LH2 and ITLR
Leaders: Rainer Helmig, Bernhard Weigand
Funding: DFG

Katharina Heck

Contact

Office Hours

Vita

Offices in the Academic Administration

publications

(Journal-) Articles

Abstract

BibTeX

Link

Abstract

BibTeX

Link

Abstract

BibTeX

Link

BibTeX

Link

BibTeX

Link

BibTeX

BibTeX

BibTeX

Theses

BibTeX

PhDs

BibTeX

Link

posters

BibTeX

supervised student assignements

Current research projects

Audience

Formalities

Services

Organization

Katharina Heck

Contact

Office Hours

Vita

Offices in the Academic Administration

publications

(Journal-) Articles

Abstract

BibTeX

Link

Abstract

BibTeX

Link

Abstract

BibTeX

Link

BibTeX

Link

BibTeX

Link

BibTeX

BibTeX

BibTeX

Theses

BibTeX

PhDs

BibTeX

Link

posters

BibTeX

supervised student assignements

Current research projects

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Formalities

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Organization