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H. J. Beine

University of California, Davis

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Featured researches published by H. J. Beine.

Environmental Science & Technology | 2010

Microorganisms in Dry Polar Snow Are Involved in the Exchanges of Reactive Nitrogen Species with the Atmosphere

A. Amoroso; Florent Domine; Giulio Esposito; S. Morin; Joel Savarino; M. Nardino; M. Montagnoli; J.-M. Bonneville; Jean-Christophe Clément; A. Ianniello; H. J. Beine

The snowpack is a complex photochemical reactor that emits a wide variety of reactive molecules to the atmosphere. In particular, the photolysis of nitrate ions, NO(3)(-), produces NO, NO(2), and HONO, which affects the oxidative capacity of the atmosphere. We report measurements in the European High Arctic where we observed for the first time emissions of NO, NO(2), and HONO by the seasonal snowpack in winter, in the complete or near-complete absence of sunlight and in the absence of melting. We also detected unusually high concentrations of nitrite ions, NO(2)(-), in the snow. These results suggest that microbial activity in the snowpack is responsible for the observed emissions. Isotopic analysis of NO(2)(-) and NO(3)(-) in the snow confirm that these ions, at least in part, do not have an atmospheric origin and are most likely produced by the microbial oxidation of NH(4)(+) coming from clay minerals into NO(2)(-) and NO(3)(-). These metabolic pathways also produce NO. Subsequent dark abiotic reactions lead to NO(2) and HONO production. The snow cover is therefore not only an active photochemical reactor but also a biogeochemical reactor active in the cycling of nitrogen and it can affect atmospheric composition all year round.

Journal of Geophysical Research | 2011

The specific surface area and chemical composition of diamond dust near Barrow, Alaska

Florent Domine; Jean Charles Gallet; Manuel Barret; Stéphan Houdier; Didier Voisin; Thomas A. Douglas; Joel D. Blum; H. J. Beine; Cort Anastasio; Franois Marie Bréon

2006, when conditions were similar. The SSA of DD ranges from 79.9 to 223 m 2 kg � 1 . The calculated ice surface area in the atmosphere reaches 11000 (� 70%) mm 2 cm � 3 , much higher than the aerosol surface area. However, the impact of DD on the downwelling and upwelling light fluxes in the UV and visible is negligible. The composition of DD is markedly different from that of snow on the surface. Its concentrations in mineral ions are much lower, and its overall composition is acidic. Its concentrations in aldehydes, DOC, H2O2 and mercury are much higher than in surface snows. Our interpretation is that DOC from the oceanic surface microlayer, coming from open leads in the ice off of Barrow, is taken up by DD. Active chemistry in the atmosphere takes place on DD crystal surfaces, explaining its high concentrations in aldehydes and mercury. After deposition, active photochemistry modifies DD composition, as seen from the modifications in its absorption spectra and aldehyde and H2O2 content. This probably leads to the emissions of reactive species to the atmosphere.

Atmospheric Chemistry and Physics | 2007

An overview of snow photochemistry: evidence, mechanisms and impacts

Amanda M. Grannas; Anna E. Jones; Jack E. Dibb; Markus Ammann; Cort Anastasio; H. J. Beine; Michael H. Bergin; J. W. Bottenheim; C. S. Boxe; G. Carver; G. Chen; J. H. Crawford; Florent Domine; Markus M. Frey; Marcelo I. Guzman; Dwayne E. Heard; Detlev Helmig; Michael R. Hoffmann; Richard E. Honrath; L. G. Huey; Manuel A. Hutterli; Hans-Werner Jacobi; Petr Klán; Barry Lefer; J. C. McConnell; John M. C. Plane; R. Sander; Joel Savarino; Paul B. Shepson; William R. Simpson

Journal of Geophysical Research | 2011

A comparison of Arctic BrO measurements by chemical ionization mass spectrometry and long path‐differential optical absorption spectroscopy

J. Liao; Holger Sihler; L. G. Huey; J. A. Neuman; David J. Tanner; U. Friess; U. Platt; F. Flocke; John J. Orlando; Paul B. Shepson; H. J. Beine; Andrew J. Weinheimer; Steven Sjostedt; J. B. Nowak; D. J. Knapp; Ralf M. Staebler; W. Zheng; R. Sander; Samuel R. Hall; Kirk Ullmann

Atmospheric Chemistry and Physics | 2004

The origin of sea salt in snow on Arctic sea ice and in coastal regions

Florent Domine; Roberto Sparapani; A. Ianniello; H. J. Beine

Atmospheric Chemistry and Physics | 2003

Fluxes of nitrates between snow surfaces and the atmosphere in the European high Arctic

H. J. Beine; Florent Domine; A. Ianniello; M. Nardino; I. Allegrini; Kimmo Teinilä; R. Hillamo

Atmospheric Chemistry and Physics | 2006

Surprisingly small HONO emissions from snow surfaces at Browning Pass, Antarctica

H. J. Beine; A. Amoroso; Florent Domine; Martin D. King; M. Nardino; A. Ianniello

Nature Geoscience | 2014

High levels of molecular chlorine in the Arctic atmosphere

Jin Liao; L. Gregory Huey; Zhen Liu; David J. Tanner; C. A. Cantrell; John J. Orlando; F. Flocke; Paul B. Shepson; Andrew J. Weinheimer; Samuel R. Hall; Kirk Ullmann; H. J. Beine; Yuhang Wang; Ellery D. Ingall; Chelsea R. Stephens; Rebecca S. Hornbrook; Eric C. Apel; Daniel D. Riemer; Alan Fried; Roy L. Mauldin; James N. Smith; Ralf M. Staebler; J. Andrew Neuman; J. B. Nowak

Journal of Geophysical Research | 2012

Frost flowers growing in the Arctic ocean‐atmosphere–sea ice–snow interface: 1. Chemical composition

Thomas A. Douglas; Florent Domine; Manuel Barret; Cort Anastasio; H. J. Beine; J. W. Bottenheim; Amanda M. Grannas; Stéphan Houdier; Stoyka Netcheva; Glenn Rowland; Ralf M. Staebler; Alexandra Steffen

Journal of Photochemistry and Photobiology A-chemistry | 2005