Retrieval of terahertz ice cloud properties from airborne measurements based on the irregularly shaped  Voronoi ice scattering models

Li, Ming; Letu, Husi; Ishimoto, Hiroshi; Li, Shulei; Liu, Lei; Nakajima, Takashi Y.; Ji, Dabin; Shang, Huazhe; Shi, Chong

doi:10.5194/amt-16-331-2023

Articles | Volume 16, issue 2

https://doi.org/10.5194/amt-16-331-2023

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

https://doi.org/10.5194/amt-16-331-2023

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

Articles | Volume 16, issue 2

Research article

|

24 Jan 2023

Research article |

| 24 Jan 2023

Retrieval of terahertz ice cloud properties from airborne measurements based on the irregularly shaped Voronoi ice scattering models

Ming Li, Husi Letu, Hiroshi Ishimoto, Shulei Li, Lei Liu, Takashi Y. Nakajima, Dabin Ji, Huazhe Shang, and Chong Shi

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Views and downloads (calculated since 08 Sep 2022)

Month	HTML	PDF	XML	Total
Sep 2022	178	46	12	236
Oct 2022	54	22	3	79
Nov 2022	67	23	8	98
Dec 2022	23	11	0	34
Jan 2023	167	40	5	212
Feb 2023	90	28	3	121
Mar 2023	27	10	0	37
Apr 2023	318	24	0	342
May 2023	41	18	4	63
Jun 2023	22	8	0	30
Jul 2023	28	19	1	48
Aug 2023	32	18	4	54
Sep 2023	41	37	2	80
Oct 2023	23	8	2	33
Nov 2023	10	10	1	21
Dec 2023	36	26	0	62
Jan 2024	17	21	0	38
Feb 2024	18	17	0	35
Mar 2024	30	31	4	65
Apr 2024	25	14	2	41
May 2024	31	13	5	49
Jun 2024	33	11	2	46
Jul 2024	65	17	5	87
Aug 2024	37	13	3	53
Sep 2024	34	12	0	46
Oct 2024	29	10	0	39
Nov 2024	23	13	1	37
Dec 2024	10	5	2	17
Jan 2025	22	19	0	41
Feb 2025	27	72	0	99
Mar 2025	32	11	0	43
Apr 2025	21	10	3	34
May 2025	22	14	2	38
Jun 2025	51	37	1	89
Jul 2025	56	34	4	94
Aug 2025	36	18	1	55
Sep 2025	40	33	1	74
Oct 2025	29	49	2	80
Nov 2025	58	35	3	96
Dec 2025	68	62	3	133
Jan 2026	73	77	11	161
Feb 2026	56	29	3	88
Mar 2026	60	27	2	89
Apr 2026	83	45	2	130
May 2026	16	8	2	26

Cumulative views and downloads (calculated since 08 Sep 2022)

Month	HTML	PDF	XML	Total
Sep 2022	178	46	12	236
Oct 2022	54	22	3	79
Nov 2022	67	23	8	98
Dec 2022	23	11	0	34
Jan 2023	167	40	5	212
Feb 2023	90	28	3	121
Mar 2023	27	10	0	37
Apr 2023	318	24	0	342
May 2023	41	18	4	63
Jun 2023	22	8	0	30
Jul 2023	28	19	1	48
Aug 2023	32	18	4	54
Sep 2023	41	37	2	80
Oct 2023	23	8	2	33
Nov 2023	10	10	1	21
Dec 2023	36	26	0	62
Jan 2024	17	21	0	38
Feb 2024	18	17	0	35
Mar 2024	30	31	4	65
Apr 2024	25	14	2	41
May 2024	31	13	5	49
Jun 2024	33	11	2	46
Jul 2024	65	17	5	87
Aug 2024	37	13	3	53
Sep 2024	34	12	0	46
Oct 2024	29	10	0	39
Nov 2024	23	13	1	37
Dec 2024	10	5	2	17
Jan 2025	22	19	0	41
Feb 2025	27	72	0	99
Mar 2025	32	11	0	43
Apr 2025	21	10	3	34
May 2025	22	14	2	38
Jun 2025	51	37	1	89
Jul 2025	56	34	4	94
Aug 2025	36	18	1	55
Sep 2025	40	33	1	74
Oct 2025	29	49	2	80
Nov 2025	58	35	3	96
Dec 2025	68	62	3	133
Jan 2026	73	77	11	161
Feb 2026	56	29	3	88
Mar 2026	60	27	2	89
Apr 2026	83	45	2	130
May 2026	16	8	2	26

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Short summary

Influenced by the representativeness of ice crystal scattering models, the existing terahertz ice cloud remote sensing inversion algorithms still have significant uncertainties. We developed an ice cloud remote sensing retrieval algorithm of the ice water path and particle size from aircraft-based terahertz radiation measurements based on the Voronoi model. Validation revealed that the Voronoi model performs better than the sphere and hexagonal column models.