Technical note: Lessons from and best practices for the  deployment of the Soil Water Isotope Storage System

Havranek, Rachel E.; Snell, Kathryn; Kopf, Sebastian; Davidheiser-Kroll, Brett; Morris, Valerie; Vaughn, Bruce

doi:10.5194/hess-27-2951-2023

Articles | Volume 27, issue 15

https://doi.org/10.5194/hess-27-2951-2023

© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

https://doi.org/10.5194/hess-27-2951-2023

© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 27, issue 15

Technical note

|

10 Aug 2023

Technical note |

| 10 Aug 2023

Technical note: Lessons from and best practices for the deployment of the Soil Water Isotope Storage System

Rachel E. Havranek, Kathryn Snell, Sebastian Kopf, Brett Davidheiser-Kroll, Valerie Morris, and Bruce Vaughn

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Total article views: 3,287 (including HTML, PDF, and XML)

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HTML: 2,186
PDF: 928
XML: 173
Total: 3,287
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BibTeX: 194
EndNote: 206

Views and downloads (calculated since 28 Oct 2022)

Month	HTML	PDF	XML	Total
Oct 2022	62	15	3	80
Nov 2022	37	27	4	68
Dec 2022	58	23	5	86
Jan 2023	17	8	0	25
Feb 2023	54	20	4	78
Mar 2023	19	10	1	30
Apr 2023	12	5	0	17
May 2023	14	8	1	23
Jun 2023	10	7	2	19
Jul 2023	8	16	6	30
Aug 2023	239	37	7	283
Sep 2023	43	20	1	64
Oct 2023	32	13	0	45
Nov 2023	36	15	1	52
Dec 2023	20	9	2	31
Jan 2024	48	12	3	63
Feb 2024	19	11	2	32
Mar 2024	27	11	2	40
Apr 2024	32	7	4	43
May 2024	46	10	5	61
Jun 2024	33	18	4	55
Jul 2024	88	13	15	116
Aug 2024	56	12	17	85
Sep 2024	32	7	39
Oct 2024	44	16	6	66
Nov 2024	37	5	0	42
Dec 2024	30	11	0	41
Jan 2025	31	19	0	50
Feb 2025	33	10	1	44
Mar 2025	35	26	0	61
Apr 2025	34	15	3	52
May 2025	47	15	0	62
Jun 2025	74	44	1	119
Jul 2025	70	30	5	105
Aug 2025	65	34	2	101
Sep 2025	80	50	11	141
Oct 2025	50	50	2	102
Nov 2025	63	54	1	118
Dec 2025	61	64	3	128
Jan 2026	74	31	13	118
Feb 2026	104	31	6	141
Mar 2026	100	50	17	167
Apr 2026	93	42	6	141
May 2026	19	4	0	23

Cumulative views and downloads (calculated since 28 Oct 2022)

Month	HTML	PDF	XML	Total
Oct 2022	62	15	3	80
Nov 2022	37	27	4	68
Dec 2022	58	23	5	86
Jan 2023	17	8	0	25
Feb 2023	54	20	4	78
Mar 2023	19	10	1	30
Apr 2023	12	5	0	17
May 2023	14	8	1	23
Jun 2023	10	7	2	19
Jul 2023	8	16	6	30
Aug 2023	239	37	7	283
Sep 2023	43	20	1	64
Oct 2023	32	13	0	45
Nov 2023	36	15	1	52
Dec 2023	20	9	2	31
Jan 2024	48	12	3	63
Feb 2024	19	11	2	32
Mar 2024	27	11	2	40
Apr 2024	32	7	4	43
May 2024	46	10	5	61
Jun 2024	33	18	4	55
Jul 2024	88	13	15	116
Aug 2024	56	12	17	85
Sep 2024	32	7	39
Oct 2024	44	16	6	66
Nov 2024	37	5	0	42
Dec 2024	30	11	0	41
Jan 2025	31	19	0	50
Feb 2025	33	10	1	44
Mar 2025	35	26	0	61
Apr 2025	34	15	3	52
May 2025	47	15	0	62
Jun 2025	74	44	1	119
Jul 2025	70	30	5	105
Aug 2025	65	34	2	101
Sep 2025	80	50	11	141
Oct 2025	50	50	2	102
Nov 2025	63	54	1	118
Dec 2025	61	64	3	128
Jan 2026	74	31	13	118
Feb 2026	104	31	6	141
Mar 2026	100	50	17	167
Apr 2026	93	42	6	141
May 2026	19	4	0	23

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Short summary

We present an automated, field-ready system that collects soil water vapor for stable isotope analysis. This system can be used to determine soil water evolution through time, which is helpful for understanding crop water use, water vapor fluxes to the atmosphere, and geologic proxy development. Our system can automatically collect soil water vapor and then store it for up to 30 d, which allows researchers to collect datasets from historically understudied, remote locations.