A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
HONO emissions from snow surfaces
Photochemical production of NOx and HONO from surface snow can significantly impact the NOx, OH, and O3 budgets in the overlying atmosphere. NOx production is driven by the solar photolysis of NO3− within or at the surface of snowpacks. HONO, however, is a secondary species that involves H-atom transfer between natural donors and photogenerated NO2. Here we investigate the mechanism of HONO generation in snowpacks by exploring how its emissions respond to on-and-off illumination and temperature cycles, and to the addition of various snow dopants. The presence of humic substances within or at the surface of the snowpack significantly enhances, and may be an essential requisite for HONO production.
Emission fluxes of NO, NO2, and HONO from snow surfaces were measured under controlled temperature, ozone mixing ratio and actinic flux conditions. We used natural mid-latitude surface snow as the snow substrate. Their combined peak emission fluxes reached up to ~3 × 1010 molecules cm−2 s−1, ~103 times larger than typical emissions from polar snowpacks. Less than 1% of available N was released in these experiments. We report significant post-irradiation HONO emissions from the snow. Present results indicate a strong, direct correlation between HONO emissions and the HULIS (humic-like substances) content of the snow surface.
HONO emissions from snow surfaces
Photochemical production of NOx and HONO from surface snow can significantly impact the NOx, OH, and O3 budgets in the overlying atmosphere. NOx production is driven by the solar photolysis of NO3− within or at the surface of snowpacks. HONO, however, is a secondary species that involves H-atom transfer between natural donors and photogenerated NO2. Here we investigate the mechanism of HONO generation in snowpacks by exploring how its emissions respond to on-and-off illumination and temperature cycles, and to the addition of various snow dopants. The presence of humic substances within or at the surface of the snowpack significantly enhances, and may be an essential requisite for HONO production.
Emission fluxes of NO, NO2, and HONO from snow surfaces were measured under controlled temperature, ozone mixing ratio and actinic flux conditions. We used natural mid-latitude surface snow as the snow substrate. Their combined peak emission fluxes reached up to ~3 × 1010 molecules cm−2 s−1, ~103 times larger than typical emissions from polar snowpacks. Less than 1% of available N was released in these experiments. We report significant post-irradiation HONO emissions from the snow. Present results indicate a strong, direct correlation between HONO emissions and the HULIS (humic-like substances) content of the snow surface.
HONO emissions from snow surfaces
HONO emissions from snow surfaces
Harry Beine (author) / Agustín J Colussi (author) / Antonio Amoroso (author) / Giulio Esposito (author) / Mauro Montagnoli (author) / Michael R Hoffmann (author)
Environmental Research Letters ; 3 ; 045005
2008-10-01
6 pages
Article (Journal)
Electronic Resource
English