Verification of a Python-based TRANsport Simulation Environment for density-driven fluid flow and coupled transport of heat and chemical species

Kempka, Thomas

doi:https://doi.org/10.5194/adgeo-54-67-2020

Articles | Volume 54

https://doi.org/10.5194/adgeo-54-67-2020

© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

https://doi.org/10.5194/adgeo-54-67-2020

© Author(s) 2020. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 54

14 Oct 2020

| 14 Oct 2020

Verification of a Python-based TRANsport Simulation Environment for density-driven fluid flow and coupled transport of heat and chemical species

Thomas Kempka

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Total article views: 1,547 (including HTML, PDF, and XML)

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PDF: 411
XML: 48
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Views and downloads (calculated since 14 Oct 2020)

Month	HTML	PDF	XML	Total
Oct 2020	80	17	2	99
Nov 2020	92	9	0	101
Dec 2020	137	11	2	150
Jan 2021	116	11	2	129
Feb 2021	17	6	0	23
Mar 2021	14	4	0	18
Apr 2021	11	6	0	17
May 2021	14	9	0	23
Jun 2021	14	5	0	19
Jul 2021	13	4	1	18
Aug 2021	14	4	2	20
Sep 2021	15	15	1	31
Oct 2021	17	26	0	43
Nov 2021	17	10	1	28
Dec 2021	14	5	1	20
Jan 2022	20	9	1	30
Feb 2022	13	10	3	26
Mar 2022	11	5	0	16
Apr 2022	11	3	0	14
May 2022	10	8	1	19
Jun 2022	4	9	3	16
Jul 2022	9	3	0	12
Aug 2022	17	4	0	21
Sep 2022	16	6	0	22
Oct 2022	12	5	0	17
Nov 2022	20	5	0	25
Dec 2022	9	13	0	22
Jan 2023	8	8	0	16
Feb 2023	12	7	0	19
Mar 2023	31	7	1	39
Apr 2023	10	8	1	19
May 2023	9	9	0	18
Jun 2023	12	14	2	28
Jul 2023	14	10	1	25
Aug 2023	5	8	2	15
Sep 2023	13	10	2	25
Oct 2023	13	8	0	21
Nov 2023	5	9	1	15
Dec 2023	15	7	4	26
Jan 2024	11	6	0	17
Feb 2024	7	11	0	18
Mar 2024	18	13	1	32
Apr 2024	18	9	4	31
May 2024	13	6	1	20
Jun 2024	25	8	2	35
Jul 2024	20	5	3	28
Aug 2024	21	1	0	22
Sep 2024	16	5	2	23
Oct 2024	15	5	1	21
Nov 2024	14	2	0	16
Dec 2024	20	11	0	31
Jan 2025	6	2	0	8

Cumulative views and downloads (calculated since 14 Oct 2020)

Month	HTML	PDF	XML	Total
Oct 2020	80	17	2	99
Nov 2020	92	9	0	101
Dec 2020	137	11	2	150
Jan 2021	116	11	2	129
Feb 2021	17	6	0	23
Mar 2021	14	4	0	18
Apr 2021	11	6	0	17
May 2021	14	9	0	23
Jun 2021	14	5	0	19
Jul 2021	13	4	1	18
Aug 2021	14	4	2	20
Sep 2021	15	15	1	31
Oct 2021	17	26	0	43
Nov 2021	17	10	1	28
Dec 2021	14	5	1	20
Jan 2022	20	9	1	30
Feb 2022	13	10	3	26
Mar 2022	11	5	0	16
Apr 2022	11	3	0	14
May 2022	10	8	1	19
Jun 2022	4	9	3	16
Jul 2022	9	3	0	12
Aug 2022	17	4	0	21
Sep 2022	16	6	0	22
Oct 2022	12	5	0	17
Nov 2022	20	5	0	25
Dec 2022	9	13	0	22
Jan 2023	8	8	0	16
Feb 2023	12	7	0	19
Mar 2023	31	7	1	39
Apr 2023	10	8	1	19
May 2023	9	9	0	18
Jun 2023	12	14	2	28
Jul 2023	14	10	1	25
Aug 2023	5	8	2	15
Sep 2023	13	10	2	25
Oct 2023	13	8	0	21
Nov 2023	5	9	1	15
Dec 2023	15	7	4	26
Jan 2024	11	6	0	17
Feb 2024	7	11	0	18
Mar 2024	18	13	1	32
Apr 2024	18	9	4	31
May 2024	13	6	1	20
Jun 2024	25	8	2	35
Jul 2024	20	5	3	28
Aug 2024	21	1	0	22
Sep 2024	16	5	2	23
Oct 2024	15	5	1	21
Nov 2024	14	2	0	16
Dec 2024	20	11	0	31
Jan 2025	6	2	0	8

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Total article views: 1,563 (including HTML, PDF, and XML) Thereof 1,561 with geography defined and 2 with unknown origin.

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Latest update: 20 Jan 2025

Short summary

The TRANsport Simulation Environment (TRANSE) has been developed to improve the flexibility for coupling chemical libraries with fluid flow and the transport of heat and chemical species. The Python-based implementation of TRANSE enables users not experienced in low-level programming languages (e.g., C, C++ or FORTRAN) to undertake required code modifications and integrate chemical modules as required. TRANSE has been successfully verified against benchmarks on density-driven fluid flow.


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Verification of a Python-based TRANsport Simulation Environment for density-driven fluid flow and coupled transport of heat and chemical species

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