Dumux code for modelling stable water isotopologue transport and fractionation
S. Kiemle, and K. Heck. Software, (2022)Related to: S. Kiemle, K. Heck, E. Coltman, R. Helmig (2022) Stable water isotopologue fractionation during soil-water evaporation: Analysis using a coupled soil-atmosphere model. (Under review). doi: 10.1002/essoar.10510931.1.
DOI: 10.18419/darus-3105
Abstract
Dumux source code to reproduce the results presented in S. Kiemle, K. Heck, E. Coltman, R. Helmig (2022) Stable water isotopologue fractionation during soil-water evaporation: Analysis using a coupled soil-atmosphere model. (Under review) Water Resources Research. The contained application allows to model stable water isotopologue transport and fractionation in soil and in the soil-atmosphere interface. The application uses a coupled porous-medium free-flow approach which allows us to derive kinetic fractionation processes without the use of further parameterization. The archive docker_image_kiemle2022a.tar corresponds to the docker image. Additionally, all required files to start the corresponding docker container are included.
Related to: S. Kiemle, K. Heck, E. Coltman, R. Helmig (2022) Stable water isotopologue fractionation during soil-water evaporation: Analysis using a coupled soil-atmosphere model. (Under review). doi: 10.1002/essoar.10510931.1
%0 Generic
%1 kiemle2022dumux
%A Kiemle, Stefanie
%A Heck, Katharina
%D 2022
%K darus mult ubs_10002 ubs_10018 ubs_20002 ubs_20023 ubs_30028 ubs_30201 ubs_40040 unibibliografie
%R 10.18419/darus-3105
%T Dumux code for modelling stable water isotopologue transport and fractionation
%X Dumux source code to reproduce the results presented in S. Kiemle, K. Heck, E. Coltman, R. Helmig (2022) Stable water isotopologue fractionation during soil-water evaporation: Analysis using a coupled soil-atmosphere model. (Under review) Water Resources Research. The contained application allows to model stable water isotopologue transport and fractionation in soil and in the soil-atmosphere interface. The application uses a coupled porous-medium free-flow approach which allows us to derive kinetic fractionation processes without the use of further parameterization. The archive docker_image_kiemle2022a.tar corresponds to the docker image. Additionally, all required files to start the corresponding docker container are included.
@misc{kiemle2022dumux,
abstract = {Dumux source code to reproduce the results presented in S. Kiemle, K. Heck, E. Coltman, R. Helmig (2022) Stable water isotopologue fractionation during soil-water evaporation: Analysis using a coupled soil-atmosphere model. (Under review) Water Resources Research. The contained application allows to model stable water isotopologue transport and fractionation in soil and in the soil-atmosphere interface. The application uses a coupled porous-medium free-flow approach which allows us to derive kinetic fractionation processes without the use of further parameterization. The archive docker_image_kiemle2022a.tar corresponds to the docker image. Additionally, all required files to start the corresponding docker container are included. },
added-at = {2022-10-12T09:04:16.000+0200},
affiliation = {Kiemle, Stefanie/Universität Stuttgart, Heck, Katharina/Universität Stuttgart},
author = {Kiemle, Stefanie and Heck, Katharina},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2226dbd54fb5e6c896125d102b73986c3/unibiblio},
doi = {10.18419/darus-3105},
howpublished = {Software},
interhash = {5fe425b569bb17e2b78a2beb64ea234f},
intrahash = {226dbd54fb5e6c896125d102b73986c3},
keywords = {darus mult ubs_10002 ubs_10018 ubs_20002 ubs_20023 ubs_30028 ubs_30201 ubs_40040 unibibliografie},
note = {Related to: S. Kiemle, K. Heck, E. Coltman, R. Helmig (2022) Stable water isotopologue fractionation during soil-water evaporation: Analysis using a coupled soil-atmosphere model. (Under review). doi: 10.1002/essoar.10510931.1},
orcid-numbers = {Kiemle, Stefanie/0000-0001-7344-0822, Heck, Katharina/0000-0002-4523-4586},
timestamp = {2022-10-12T07:04:16.000+0200},
title = {Dumux code for modelling stable water isotopologue transport and fractionation},
year = 2022
}
