An overview of snow photochemistry: evidence, mechanisms and
impacts

GRANNAS, A. M., A. E. JONES, J. DIBB, M. AMMAN, C. ANASTASIO, H. J. BEINE, M. BERGIN, J. BOTTENHEIM, C. S. BOXE, G. CARVER, G. CHEN, J. H. CRAWFORD, F. DOMINE, M. M. FREY, M. I. GUZMAN, D. E. HEARD, D. HELMIG, M. R. HOFFMANN, R. E. HONRATH, L. G. HUEY, M. HUTTERLI, H. W. JACOBI, Petr KLÁN, B. LEFER, J. MCCONNELL, J. PLANE, R. SANDER, J. SAVARINO, P. B. SHEPSON, W. R. SIMPSON, J. R. SODEAU, R. VON GLASOW, R. WELLER, E. W. WOLFF a T. ZHU. An overview of snow photochemistry: evidence, mechanisms and impacts. Atmospheric Chemistry and Physics Discussions. Strasbourg, France: European Geosciences Union, 2007, roč. 7, č. 2, s. 4329–4373, 44 s. ISSN 1680-7316.

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TY  - JOUR
ID  - 719736
AU  - Grannas, A. M. - Jones, A. E. - Dibb, J. - Amman, M. - Anastasio, C. - Beine, H. J. - Bergin, M. - Bottenheim, J. - Boxe, C. S. - Carver, G. - Chen, G. - Crawford, J. H. - Domine, F. - Frey, M. M. - Guzman, M. I. - Heard, D. E. - Helmig, D. - Hoffmann, M. R. - Honrath, R. E. - Huey, L. G. - Hutterli, M. - Jacobi, H. W. - Klán, Petr - Lefer, B. - McConnell, J. - Plane, J. - Sander, R. - Savarino, J. - Shepson, P. B. - Simpson, W. R. - Sodeau, J. R. - von Glasow, R. - Weller, R. - Wolff, E. W. - Zhu, T.
PY  - 2007
TI  - An overview of snow photochemistry: evidence, mechanisms and impacts
JF  - Atmospheric Chemistry and Physics Discussions
VL  - 7
IS  - 2
SP  - 4329–4373
EP  - 4329–4373
PB  - European Geosciences Union
SN  - 16807316
KW  - Photochemistry
KW  - snow
KW  - review
N2  - It has been shown that sunlit snow and ice plays an important role in processing atmospheric species. Photochemical production of a variety of chemicals has recently been reported to occur in snow/ice and the release of these photochemically generated 5 species may significantly impact the chemistry of the overlying atmosphere. Nitrogen oxide and oxidant precursor fluxes have been measured in a number of snow covered environments, where in some cases the emissions significantly impact the overlying boundary layer. For example, photochemical ozone production (such as that occurring in polluted mid-latitudes) of 3-4 ppbv/day has been observed at South Pole, due 10 to high OH and NO levels present in a relatively shallow boundary layer. Field and laboratory experiments have determined that the origin of the observed NOx flux is the photochemistry of nitrate within the snowpack, however some details of the mechanism have not yet been elucidated. A variety of low molecular weight organic compounds have been shown to be emitted from sunlit snowpacks, the source of which 15 has been proposed to be either direct or indirect photooxidation of natural organic materials present in the snow. Although myriad studies have observed active processing of species within irradiated snowpacks, the fundamental chemistry occurring remains poorly understood. Here we consider the nature of snow at a fundamental, physical level; photochemical processes within snow and the caveats needed for comparison to 20 atmospheric photochemistry; our current understanding of nitrogen, oxidant, halogen and organic photochemistry within snow; the current limitations faced by the field and implications for the future.
ER  -

Základní údaje
Originální název	An overview of snow photochemistry: evidence, mechanisms and impacts
Název česky	Fotochemie ve sněhu: důkaz, mechanismus a důsledky
Autoři	GRANNAS, A. M. (840 Spojené státy), A. E. JONES (826 Velká Británie a Severní Irsko), J. DIBB (840 Spojené státy), M. AMMAN (756 Švýcarsko), C. ANASTASIO (840 Spojené státy), H. J. BEINE (380 Itálie), M. BERGIN (840 Spojené státy), J. BOTTENHEIM (124 Kanada), C. S. BOXE (840 Spojené státy), G. CARVER (826 Velká Británie a Severní Irsko), G. CHEN (840 Spojené státy), J. H. CRAWFORD (840 Spojené státy), F. DOMINE (250 Francie), M. M. FREY (840 Spojené státy), M. I. GUZMAN (840 Spojené státy), D. E. HEARD (826 Velká Británie a Severní Irsko), D. HELMIG (840 Spojené státy), M. R. HOFFMANN (840 Spojené státy), R. E. HONRATH (840 Spojené státy), L. G. HUEY (840 Spojené státy), M. HUTTERLI (826 Velká Británie a Severní Irsko), H. W. JACOBI (276 Německo), Petr KLÁN (203 Česká republika, garant), B. LEFER (840 Spojené státy), J. MCCONNELL (124 Kanada), J. PLANE (826 Velká Británie a Severní Irsko), R. SANDER (276 Německo), J. SAVARINO (380 Itálie), P. B. SHEPSON (840 Spojené státy), W. R. SIMPSON (840 Spojené státy), J. R. SODEAU (372 Irsko), R. VON GLASOW (826 Velká Británie a Severní Irsko), R. WELLER (276 Německo), E. W. WOLFF (826 Velká Británie a Severní Irsko) a T. ZHU (156 Čína).
Vydání	Atmospheric Chemistry and Physics Discussions, Strasbourg, France, European Geosciences Union, 2007, 1680-7316.

Další údaje
Originální jazyk	angličtina
Typ výsledku	Článek v odborném periodiku
Obor	10401 Organic chemistry
Stát vydavatele	Francie
Utajení	není předmětem státního či obchodního tajemství
Impakt faktor	Impact factor: 4.865
Kód RIV	RIV/00216224:14310/07:00020318
Organizační jednotka	Přírodovědecká fakulta
UT WoS	000249072900013
Klíčová slova anglicky	Photochemistry; snow; review
Štítky	Photochemistry, Review, snow
Příznaky	Mezinárodní význam, Recenzováno
Změnil	Změnil: prof. RNDr. Petr Klán, Ph.D., učo 32829. Změněno: 23. 6. 2009 15:12.

Anotace

It has been shown that sunlit snow and ice plays an important role in processing atmospheric species. Photochemical production of a variety of chemicals has recently been reported to occur in snow/ice and the release of these photochemically generated 5 species may significantly impact the chemistry of the overlying atmosphere. Nitrogen oxide and oxidant precursor fluxes have been measured in a number of snow covered environments, where in some cases the emissions significantly impact the overlying boundary layer. For example, photochemical ozone production (such as that occurring in polluted mid-latitudes) of 3-4 ppbv/day has been observed at South Pole, due 10 to high OH and NO levels present in a relatively shallow boundary layer. Field and laboratory experiments have determined that the origin of the observed NOx flux is the photochemistry of nitrate within the snowpack, however some details of the mechanism have not yet been elucidated. A variety of low molecular weight organic compounds have been shown to be emitted from sunlit snowpacks, the source of which 15 has been proposed to be either direct or indirect photooxidation of natural organic materials present in the snow. Although myriad studies have observed active processing of species within irradiated snowpacks, the fundamental chemistry occurring remains poorly understood. Here we consider the nature of snow at a fundamental, physical level; photochemical processes within snow and the caveats needed for comparison to 20 atmospheric photochemistry; our current understanding of nitrogen, oxidant, halogen and organic photochemistry within snow; the current limitations faced by the field and implications for the future.

Anotace česky

It has been shown that sunlit snow and ice plays an important role in processing atmospheric species. Photochemical production of a variety of chemicals has recently been reported to occur in snow/ice and the release of these photochemically generated 5 species may significantly impact the chemistry of the overlying atmosphere. Nitrogen oxide and oxidant precursor fluxes have been measured in a number of snow covered environments, where in some cases the emissions significantly impact the overlying boundary layer. For example, photochemical ozone production (such as that occurring in polluted mid-latitudes) of 3-4 ppbv/day has been observed at South Pole, due 10 to high OH and NO levels present in a relatively shallow boundary layer. Field and laboratory experiments have determined that the origin of the observed NOx flux is the photochemistry of nitrate within the snowpack, however some details of the mechanism have not yet been elucidated. A variety of low molecular weight organic compounds have been shown to be emitted from sunlit snowpacks, the source of which 15 has been proposed to be either direct or indirect photooxidation of natural organic materials present in the snow. Although myriad studies have observed active processing of species within irradiated snowpacks, the fundamental chemistry occurring remains poorly understood. Here we consider the nature of snow at a fundamental, physical level; photochemical processes within snow and the caveats needed for comparison to 20 atmospheric photochemistry; our current understanding of nitrogen, oxidant, halogen and organic photochemistry within snow; the current limitations faced by the field and implications for the future.

Návaznosti
GA205/05/0819, projekt VaV	Název: Environmentální důsledky fotochemických transformací v ledu a sněhu
GA205/05/0819, projekt VaV	Investor: Grantová agentura ČR, Environmentální důsledky fotochemických transformací v ledu a sněhu
MSM0021622412, záměr	Název: Interakce mezi chemickými látkami, prostředím a biologickými systémy a jejich důsledky na globální, regionální a lokální úrovni (INCHEMBIOL) (Akronym: INCHEMBIOL)
MSM0021622412, záměr	Investor: Ministerstvo školství, mládeže a tělovýchovy ČR, Interakce mezi chemickými látkami, prostředím a biologickými systémy a jejich důsledky na globální , regionální a lokální úrovni

VytisknoutZobrazeno: 12. 5. 2024 09:30

An overview of snow photochemistry: evidence, mechanisms and impacts

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