An improved model of shade-affected stream temperature in Soil &amp; Water Assessment Tool

Noa-Yarasca, Efrain; Babbar-Sebens, Meghna; Jordan, Chris

doi:10.5194/hess-27-739-2023

Articles | Volume 27, issue 3

https://doi.org/10.5194/hess-27-739-2023

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

Special issue:

Experiments in Hydrology and Hydraulics

https://doi.org/10.5194/hess-27-739-2023

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

Articles | Volume 27, issue 3

Research article

|

10 Feb 2023

Research article |

| 10 Feb 2023

An improved model of shade-affected stream temperature in Soil & Water Assessment Tool

Efrain Noa-Yarasca, Meghna Babbar-Sebens, and Chris Jordan

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Total article views: 5,627 (including HTML, PDF, and XML)

HTML	PDF	XML	Total	Supplement	BibTeX	EndNote
2,616	2,905	106	5,627	374	94	126

HTML: 2,616
PDF: 2,905
XML: 106
Total: 5,627
Supplement: 374
BibTeX: 94
EndNote: 126

Views and downloads (calculated since 23 Aug 2022)

Month	HTML	PDF	XML	Total
Aug 2022	167	37	3	207
Sep 2022	88	18	6	112
Oct 2022	49	16	2	67
Nov 2022	94	27	11	132
Dec 2022	15	6	0	21
Jan 2023	18	20	0	38
Feb 2023	262	2,037	5	2,304
Mar 2023	77	27	3	107
Apr 2023	85	18	2	105
May 2023	51	24	1	76
Jun 2023	50	15	2	67
Jul 2023	66	37	3	106
Aug 2023	46	21	3	70
Sep 2023	39	15	2	56
Oct 2023	43	23	1	67
Nov 2023	21	4	0	25
Dec 2023	27	20	1	48
Jan 2024	45	11	4	60
Feb 2024	28	24	0	52
Mar 2024	47	24	2	73
Apr 2024	50	10	2	62
May 2024	38	14	7	59
Jun 2024	46	13	2	61
Jul 2024	61	6	4	71
Aug 2024	56	19	3	78
Sep 2024	41	5	0	46
Oct 2024	36	8	1	45
Nov 2024	44	8	0	52
Dec 2024	24	13	1	38
Jan 2025	29	18	0	47
Feb 2025	31	7	0	38
Mar 2025	47	18	5	70
Apr 2025	36	5	1	42
May 2025	48	6	0	54
Jun 2025	65	43	0	108
Jul 2025	28	19	3	50
Aug 2025	46	14	3	63
Sep 2025	121	36	2	159
Oct 2025	49	37	1	87
Nov 2025	43	38	3	84
Dec 2025	64	35	1	100
Jan 2026	69	27	9	105
Feb 2026	80	22	3	105
Mar 2026	57	25	2	84
Apr 2026	85	35	2	122
May 2026	4	0	4

Cumulative views and downloads (calculated since 23 Aug 2022)

Month	HTML	PDF	XML	Total
Aug 2022	167	37	3	207
Sep 2022	88	18	6	112
Oct 2022	49	16	2	67
Nov 2022	94	27	11	132
Dec 2022	15	6	0	21
Jan 2023	18	20	0	38
Feb 2023	262	2,037	5	2,304
Mar 2023	77	27	3	107
Apr 2023	85	18	2	105
May 2023	51	24	1	76
Jun 2023	50	15	2	67
Jul 2023	66	37	3	106
Aug 2023	46	21	3	70
Sep 2023	39	15	2	56
Oct 2023	43	23	1	67
Nov 2023	21	4	0	25
Dec 2023	27	20	1	48
Jan 2024	45	11	4	60
Feb 2024	28	24	0	52
Mar 2024	47	24	2	73
Apr 2024	50	10	2	62
May 2024	38	14	7	59
Jun 2024	46	13	2	61
Jul 2024	61	6	4	71
Aug 2024	56	19	3	78
Sep 2024	41	5	0	46
Oct 2024	36	8	1	45
Nov 2024	44	8	0	52
Dec 2024	24	13	1	38
Jan 2025	29	18	0	47
Feb 2025	31	7	0	38
Mar 2025	47	18	5	70
Apr 2025	36	5	1	42
May 2025	48	6	0	54
Jun 2025	65	43	0	108
Jul 2025	28	19	3	50
Aug 2025	46	14	3	63
Sep 2025	121	36	2	159
Oct 2025	49	37	1	87
Nov 2025	43	38	3	84
Dec 2025	64	35	1	100
Jan 2026	69	27	9	105
Feb 2026	80	22	3	105
Mar 2026	57	25	2	84
Apr 2026	85	35	2	122
May 2026	4	0	4

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Latest update: 02 May 2026

Short summary

Riparian vegetation has been identified as a strategy to control rising stream temperatures by shading streams. Riparian vegetation is included within a sub-basin-scale hydrological model and evaluated for full and efficient restoration scenarios. Results showed average temperature reductions of 0.91 and 0.86 °C for full and efficient riparian restoration, respectively. Notwithstanding the similar benefits, efficient restoration was 14.4 % cheaper than full riparian vegetation restoration.