Representing farmer irrigated crop area adaptation  in a large-scale hydrological model

Yoon, Jim; Voisin, Nathalie; Klassert, Christian; Thurber, Travis; Xu, Wenwei

doi:10.5194/hess-28-899-2024

Articles | Volume 28, issue 4

https://doi.org/10.5194/hess-28-899-2024

© Author(s) 2024. This work is distributed under
the Creative Commons Attribution 4.0 License.

Special issue:

Representation of water infrastructures in large-scale hydrological...

https://doi.org/10.5194/hess-28-899-2024

© Author(s) 2024. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 28, issue 4

Research article

|

27 Feb 2024

Research article |

| 27 Feb 2024

Representing farmer irrigated crop area adaptation in a large-scale hydrological model

Jim Yoon, Nathalie Voisin, Christian Klassert, Travis Thurber, and Wenwei Xu

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Feb 2025	51	17	3	71
Mar 2025	68	31	3	102
Apr 2025	43	33	5	81
May 2025	57	23	2	82
Jun 2025	80	61	0	141
Jul 2025	64	33	5	102
Aug 2025	110	39	1	150
Sep 2025	392	39	6	437
Oct 2025	50	51	2	103
Nov 2025	97	67	2	166
Dec 2025	93	58	1	152
Jan 2026	106	97	11	214
Feb 2026	137	48	10	195
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Apr 2026	112	118	4	234
May 2026	36	41	2	79

Cumulative views and downloads (calculated since 20 Jul 2023)

Month	HTML	PDF	XML	Total
Jul 2023	84	39	5	128
Aug 2023	64	16	3	83
Sep 2023	32	14	5	51
Oct 2023	33	7	2	42
Nov 2023	12	4	1	17
Dec 2023	16	7	1	24
Jan 2024	15	2	0	17
Feb 2024	207	49	4	260
Mar 2024	210	55	6	271
Apr 2024	96	35	3	134
May 2024	93	45	14	152
Jun 2024	103	24	6	133
Jul 2024	113	14	8	135
Aug 2024	103	12	6	121
Sep 2024	82	13	0	95
Oct 2024	60	24	1	85
Nov 2024	71	13	0	84
Dec 2024	62	27	1	90
Jan 2025	42	15	3	60
Feb 2025	51	17	3	71
Mar 2025	68	31	3	102
Apr 2025	43	33	5	81
May 2025	57	23	2	82
Jun 2025	80	61	0	141
Jul 2025	64	33	5	102
Aug 2025	110	39	1	150
Sep 2025	392	39	6	437
Oct 2025	50	51	2	103
Nov 2025	97	67	2	166
Dec 2025	93	58	1	152
Jan 2026	106	97	11	214
Feb 2026	137	48	10	195
Mar 2026	167	232	10	409
Apr 2026	112	118	4	234
May 2026	36	41	2	79

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Short summary

Global and regional models used to evaluate water shortages typically neglect the possibility that irrigated crop areas may change in response to future hydrological conditions, such as the fallowing of crops in response to drought. Here, we enhance a model used for water shortage analysis with farmer agents that dynamically adapt their irrigated crop areas based on simulated hydrological conditions. Results indicate that such cropping adaptation can strongly alter simulated water shortages.


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