Understanding the influence of “hot” models in climate  impact studies: a hydrological perspective

Rahimpour Asenjan, Mehrad; Brissette, Francois; Martel, Jean-Luc; Arsenault, Richard

doi:10.5194/hess-27-4355-2023

Articles | Volume 27, issue 23

https://doi.org/10.5194/hess-27-4355-2023

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

https://doi.org/10.5194/hess-27-4355-2023

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

Articles | Volume 27, issue 23

Research article

|

11 Dec 2023

Research article |

| 11 Dec 2023

Understanding the influence of “hot” models in climate impact studies: a hydrological perspective

Mehrad Rahimpour Asenjan, Francois Brissette, Jean-Luc Martel, and Richard Arsenault

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Total article views: 4,233 (including HTML, PDF, and XML)

HTML	PDF	XML	Total	Supplement	BibTeX	EndNote
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HTML: 2,674
PDF: 1,451
XML: 108
Total: 4,233
Supplement: 119
BibTeX: 105
EndNote: 137

Views and downloads (calculated since 27 Feb 2023)

Month	HTML	PDF	XML	Total
Feb 2023	90	14	2	106
Mar 2023	163	79	4	246
Apr 2023	54	20	2	76
May 2023	67	15	6	88
Jun 2023	48	15	2	65
Jul 2023	50	42	1	93
Aug 2023	40	35	1	76
Sep 2023	26	37	3	66
Oct 2023	30	23	0	53
Nov 2023	24	14	0	38
Dec 2023	264	69	9	342
Jan 2024	96	76	1	173
Feb 2024	49	53	0	102
Mar 2024	52	47	1	100
Apr 2024	53	34	6	93
May 2024	35	27	5	67
Jun 2024	80	32	2	114
Jul 2024	73	22	2	97
Aug 2024	87	13	6	106
Sep 2024	64	19	2	85
Oct 2024	47	28	1	76
Nov 2024	30	16	0	46
Dec 2024	25	22	1	48
Jan 2025	43	33	5	81
Feb 2025	31	13	0	44
Mar 2025	41	12	0	53
Apr 2025	61	30	6	97
May 2025	53	27	1	81
Jun 2025	70	27	1	98
Jul 2025	44	23	3	70
Aug 2025	51	32	3	86
Sep 2025	152	30	1	183
Oct 2025	54	34	1	89
Nov 2025	75	71	2	148
Dec 2025	98	162	4	264
Jan 2026	62	60	8	130
Feb 2026	136	31	7	174
Mar 2026	48	28	4	80
Apr 2026	108	86	5	199

Cumulative views and downloads (calculated since 27 Feb 2023)

Month	HTML	PDF	XML	Total
Feb 2023	90	14	2	106
Mar 2023	163	79	4	246
Apr 2023	54	20	2	76
May 2023	67	15	6	88
Jun 2023	48	15	2	65
Jul 2023	50	42	1	93
Aug 2023	40	35	1	76
Sep 2023	26	37	3	66
Oct 2023	30	23	0	53
Nov 2023	24	14	0	38
Dec 2023	264	69	9	342
Jan 2024	96	76	1	173
Feb 2024	49	53	0	102
Mar 2024	52	47	1	100
Apr 2024	53	34	6	93
May 2024	35	27	5	67
Jun 2024	80	32	2	114
Jul 2024	73	22	2	97
Aug 2024	87	13	6	106
Sep 2024	64	19	2	85
Oct 2024	47	28	1	76
Nov 2024	30	16	0	46
Dec 2024	25	22	1	48
Jan 2025	43	33	5	81
Feb 2025	31	13	0	44
Mar 2025	41	12	0	53
Apr 2025	61	30	6	97
May 2025	53	27	1	81
Jun 2025	70	27	1	98
Jul 2025	44	23	3	70
Aug 2025	51	32	3	86
Sep 2025	152	30	1	183
Oct 2025	54	34	1	89
Nov 2025	75	71	2	148
Dec 2025	98	162	4	264
Jan 2026	62	60	8	130
Feb 2026	136	31	7	174
Mar 2026	48	28	4	80
Apr 2026	108	86	5	199

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Total article views: 4,233 (including HTML, PDF, and XML) Thereof 4,149 with geography defined and 84 with unknown origin.

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Latest update: 30 Apr 2026

Short summary

Climate models are central to climate change impact studies. Some models project a future deemed too hot by many. We looked at how including hot models may skew the result of impact studies. Applied to hydrology, this study shows that hot models do not systematically produce hydrological outliers.