Contributions to local- and regional-scale formaldehyde concentrations

Bastien, Lucas A. J.; Brown, Nancy J.; Harley, Robert A.

doi:https://doi.org/10.5194/acp-19-8363-2019

Articles | Volume 19, issue 13

Atmos. Chem. Phys., 19, 8363–8381, 2019

https://doi.org/10.5194/acp-19-8363-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

Atmos. Chem. Phys., 19, 8363–8381, 2019

https://doi.org/10.5194/acp-19-8363-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 19, issue 13

Research article

02 Jul 2019

Research article | 02 Jul 2019

Contributions to local- and regional-scale formaldehyde concentrations

Lucas A. J. Bastien et al.

Viewed

Total article views: 1,541 (including HTML, PDF, and XML)

HTML	PDF	XML	Total	Supplement	BibTeX	EndNote
1,039	474	28	1,541	162	25	34

HTML: 1,039
PDF: 474
XML: 28
Total: 1,541
Supplement: 162
BibTeX: 25
EndNote: 34

Views and downloads (calculated since 27 Nov 2018)

Month	HTML	PDF	XML	Total
Nov 2018	136	42	2	180
Dec 2018	82	14	1	97
Jan 2019	14	6	0	20
Feb 2019	5	2	0	7
Mar 2019	6	4	0	10
Apr 2019	7	6	0	13
May 2019	8	9	1	18
Jun 2019	4	5	0	9
Jul 2019	242	65	6	313
Aug 2019	37	25	2	64
Sep 2019	57	10	0	67
Oct 2019	29	13	3	45
Nov 2019	20	10	0	30
Dec 2019	13	8	0	21
Jan 2020	16	4	0	20
Feb 2020	16	8	2	26
Mar 2020	8	7	0	15
Apr 2020	9	3	0	12
May 2020	21	9	0	30
Jun 2020	16	9	0	25
Jul 2020	19	9	3	31
Aug 2020	18	10	0	28
Sep 2020	12	5	1	18
Oct 2020	15	6	0	21
Nov 2020	17	13	0	30
Dec 2020	6	2	0	8
Jan 2021	16	8	0	24
Feb 2021	12	5	0	17
Mar 2021	11	8	0	19
Apr 2021	9	6	0	15
May 2021	11	13	0	24
Jun 2021	21	9	0	30
Jul 2021	10	8	0	18
Aug 2021	16	14	0	30
Sep 2021	18	5	0	23
Oct 2021	8	28	1	37
Nov 2021	15	26	1	42
Dec 2021	13	10	1	24
Jan 2022	9	9	0	18
Feb 2022	11	6	2	19
Mar 2022	7	7	0	14
Apr 2022	7	3	1	11
May 2022	5	2	0	7
Jun 2022	7	3	1	11

Cumulative views and downloads (calculated since 27 Nov 2018)

Month	HTML	PDF	XML	Total
Nov 2018	136	42	2	180
Dec 2018	82	14	1	97
Jan 2019	14	6	0	20
Feb 2019	5	2	0	7
Mar 2019	6	4	0	10
Apr 2019	7	6	0	13
May 2019	8	9	1	18
Jun 2019	4	5	0	9
Jul 2019	242	65	6	313
Aug 2019	37	25	2	64
Sep 2019	57	10	0	67
Oct 2019	29	13	3	45
Nov 2019	20	10	0	30
Dec 2019	13	8	0	21
Jan 2020	16	4	0	20
Feb 2020	16	8	2	26
Mar 2020	8	7	0	15
Apr 2020	9	3	0	12
May 2020	21	9	0	30
Jun 2020	16	9	0	25
Jul 2020	19	9	3	31
Aug 2020	18	10	0	28
Sep 2020	12	5	1	18
Oct 2020	15	6	0	21
Nov 2020	17	13	0	30
Dec 2020	6	2	0	8
Jan 2021	16	8	0	24
Feb 2021	12	5	0	17
Mar 2021	11	8	0	19
Apr 2021	9	6	0	15
May 2021	11	13	0	24
Jun 2021	21	9	0	30
Jul 2021	10	8	0	18
Aug 2021	16	14	0	30
Sep 2021	18	5	0	23
Oct 2021	8	28	1	37
Nov 2021	15	26	1	42
Dec 2021	13	10	1	24
Jan 2022	9	9	0	18
Feb 2022	11	6	2	19
Mar 2022	7	7	0	14
Apr 2022	7	3	1	11
May 2022	5	2	0	7
Jun 2022	7	3	1	11

Viewed (geographical distribution)

Total article views: 1,392 (including HTML, PDF, and XML) Thereof 1,382 with geography defined and 10 with unknown origin.

Country	#	Views	%

1

1

Latest update: 29 Jun 2022

Short summary

This work uses a computer model to identify emission sources and chemical reactions that influence ambient formaldehyde (a carcinogenic pollutant) in the San Francisco Bay Area. Results suggest that for some locations, in order to reduce summer-season formaldehyde concentrations, controlling emissions of other pollutants can be as efficient as controlling emissions of formaldehyde. In winter, however, it is more efficient to control emissions of formaldehyde than emissions of other species.


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