Evaluation of a cloudy cold-air pool in the Columbia River basin in different versions of the High-Resolution Rapid Refresh  (HRRR) model

Adler, Bianca; Wilczak, James M.; Kenyon, Jaymes; Bianco, Laura; Djalalova, Irina V.; Olson, Joseph B.; Turner, David D.

doi:10.5194/gmd-16-597-2023

Articles | Volume 16, issue 2

https://doi.org/10.5194/gmd-16-597-2023

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

https://doi.org/10.5194/gmd-16-597-2023

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

Articles | Volume 16, issue 2

Model evaluation paper

|

26 Jan 2023

Model evaluation paper |

| 26 Jan 2023

Evaluation of a cloudy cold-air pool in the Columbia River basin in different versions of the High-Resolution Rapid Refresh (HRRR) model

Bianca Adler, James M. Wilczak, Jaymes Kenyon, Laura Bianco, Irina V. Djalalova, Joseph B. Olson, and David D. Turner

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Total article views: 4,720 (including HTML, PDF, and XML)

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3,048	1,533	139	4,720	223	327

HTML: 3,048
PDF: 1,533
XML: 139
Total: 4,720
BibTeX: 223
EndNote: 327

Views and downloads (calculated since 19 Jul 2022)

Month	HTML	PDF	XML	Total
Jul 2022	85	19	5	109
Aug 2022	52	9	1	62
Sep 2022	44	7	0	51
Oct 2022	64	8	4	76
Nov 2022	64	10	2	76
Dec 2022	37	8	0	45
Jan 2023	126	21	4	151
Feb 2023	87	13	2	102
Mar 2023	35	12	0	47
Apr 2023	403	9	0	412
May 2023	19	5	1	25
Jun 2023	16	8	0	24
Jul 2023	16	9	1	26
Aug 2023	13	5	1	19
Sep 2023	20	11	1	32
Oct 2023	24	5	1	30
Nov 2023	10	6	0	16
Dec 2023	23	16	1	40
Jan 2024	32	5	1	38
Feb 2024	9	9	0	18
Mar 2024	14	20	3	37
Apr 2024	22	4	1	27
May 2024	29	18	8	55
Jun 2024	52	14	4	70
Jul 2024	24	7	5	36
Aug 2024	46	8	6	60
Sep 2024	31	8	1	40
Oct 2024	14	10	0	24
Nov 2024	14	5	1	20
Dec 2024	16	5	1	22
Jan 2025	29	23	11	63
Feb 2025	37	4	3	44
Mar 2025	31	38	6	75
Apr 2025	31	23	2	56
May 2025	40	10	0	50
Jun 2025	44	58	1	103
Jul 2025	50	26	4	80
Aug 2025	54	24	4	82
Sep 2025	228	49	4	281
Oct 2025	64	37	3	104
Nov 2025	91	62	3	156
Dec 2025	103	54	3	160
Jan 2026	263	138	17	418
Feb 2026	228	48	1	277
Mar 2026	99	314	12	425
Apr 2026	124	206	2	332
May 2026	84	116	7	207
Jun 2026	7	9	1	17

Cumulative views and downloads (calculated since 19 Jul 2022)

Month	HTML	PDF	XML	Total
Jul 2022	85	19	5	109
Aug 2022	52	9	1	62
Sep 2022	44	7	0	51
Oct 2022	64	8	4	76
Nov 2022	64	10	2	76
Dec 2022	37	8	0	45
Jan 2023	126	21	4	151
Feb 2023	87	13	2	102
Mar 2023	35	12	0	47
Apr 2023	403	9	0	412
May 2023	19	5	1	25
Jun 2023	16	8	0	24
Jul 2023	16	9	1	26
Aug 2023	13	5	1	19
Sep 2023	20	11	1	32
Oct 2023	24	5	1	30
Nov 2023	10	6	0	16
Dec 2023	23	16	1	40
Jan 2024	32	5	1	38
Feb 2024	9	9	0	18
Mar 2024	14	20	3	37
Apr 2024	22	4	1	27
May 2024	29	18	8	55
Jun 2024	52	14	4	70
Jul 2024	24	7	5	36
Aug 2024	46	8	6	60
Sep 2024	31	8	1	40
Oct 2024	14	10	0	24
Nov 2024	14	5	1	20
Dec 2024	16	5	1	22
Jan 2025	29	23	11	63
Feb 2025	37	4	3	44
Mar 2025	31	38	6	75
Apr 2025	31	23	2	56
May 2025	40	10	0	50
Jun 2025	44	58	1	103
Jul 2025	50	26	4	80
Aug 2025	54	24	4	82
Sep 2025	228	49	4	281
Oct 2025	64	37	3	104
Nov 2025	91	62	3	156
Dec 2025	103	54	3	160
Jan 2026	263	138	17	418
Feb 2026	228	48	1	277
Mar 2026	99	314	12	425
Apr 2026	124	206	2	332
May 2026	84	116	7	207
Jun 2026	7	9	1	17

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Total article views: 4,720 (including HTML, PDF, and XML) Thereof 4,660 with geography defined and 60 with unknown origin.

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Short summary

Rapid changes in wind speed make the integration of wind energy produced during persistent orographic cold-air pools difficult to integrate into the electrical grid. By evaluating three versions of NOAA’s High-Resolution Rapid Refresh model, we demonstrate how model developments targeted during the second Wind Forecast Improvement Project improve the forecast of a persistent cold-air pool event.