Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
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Stratospheric controlled perturbation experiment: a small-scale experiment to improve understanding of the risks of solar geoengineering.Kinetics of the ClO + HO2 reaction over the temperature range T = 210-298 K.Arabidopsis Flavonoid Mutants Are Hypersensitive to UV-B Irradiation.UV dosage levels in summer: increased risk of ozone loss from convectively injected water vapor.UV radiation and freshwater zooplankton: damage, protection and recoveryChlorofluorocarbons and ozone.Solar UVB-induced DNA damage and photoenzymatic DNA repair in antarctic zooplankton.Stratospheric ozone over the United States in summer linked to observations of convection and temperature via chlorine and bromine catalysis.Agricultural soil fumigation as a source of atmospheric methyl bromide.Mechanisms for the breakdown of halomethanes through reactions with ground-state cyano radicals.Interhemispheric Differences in Polar Stratospheric HNO3, H2O, CIO, and O3.Halocarbons produced by natural oxidation processes during degradation of organic matter.Metabolomics reveals comprehensive reprogramming involving two independent metabolic responses of Arabidopsis to UV-B light.Decadal evolution of the Antarctic ozone hole.Exploring the potential energy surface of novel [H, S, Se, Br] species: a high level first principle study.Effect of a single water molecule on the HO2 + ClO reaction.Quantum chemical study of atmospheric aggregates: HCl•HNO3•H2SO4.DNA damage and repair in plants under ultraviolet and ionizing radiations.Tracing the flow of North Atlantic Deep Water using chlorofluorocarbonsNew fast response photofragment fluorescence hygrometer for use on the NASA ER‐2 and the Perseus remotely piloted aircraftIn-Vivo NMR Spectroscopy: A Powerful and Complimentary Tool for Understanding Environmental ToxicityThe ground and excited states of HBrO2 [HOOBr, HOBrO, and HBr(O)O] and HBrO3 (HOOOBr and HOOBrO) isomersA test of our understanding of the ozone chemistry in the Arctic polar vortex based on in situ measurements of ClO, BrO, and O3in the 1994/1995 winterEstimates of total organic and inorganic chlorine in the lower stratosphere from in situ and flask measurements during AASE IISatellite observations of temporary and irreversible denitrificationDevelopment of the Antarctic ozone holeBalloon-borne in situ measurements of CLO and ozone: Implications for heterogeneous chemistry and mid-latitude ozone lossBalloon-borne measurements of CLO, NO, and O3in a volcanic cloud: An analysis of heterogeneous chemistry between 20 and 30 kmIn situ measurements of BrO During AASE IIPhotochemical partitioning of the reactive nitrogen and chlorine reservoirs in the high-latitude stratosphereThe kinetics of the ClOOCl catalytic cycleOn the potential importance of the gas phase reaction CH3O2+ ClO → ClOO + CH3O and the heterogeneous reaction HOCl + HCl → H2O + Cl2in “ozone hole” chemistryStratosphere over Dumont d'Urville, Antarctica, in winter 1992Airborne heterodyne measurements of stratospheric ClO, HCl, O3, and N2O during SESAME 1 over northern EuropeChlorine deactivation in the lower stratospheric polar regions during late winter: Results from UARSA three-dimensional modeling study of trace species in the Arctic lower stratosphere during winter 1989-1990The effect of climate change on ozone depletion through changes in stratospheric water vapourHALOE observations of the Arctic Vortex during the 1997 spring: Horizontal structure in the lower stratosphereAn extensiveab initiostudy of the structures, vibrational spectra, quadratic force fields, and relative energetics of three isomers of Cl2O2How many molecules make a solution?
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Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
description
article publié dans la revue scientifique Science
@fr
im Januar 1991 veröffentlichter wissenschaftlicher Artikel
@de
scientific article published in Science
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована в січні 1991
@uk
name
Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
@en
Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
@nl
type
label
Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
@en
Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
@nl
prefLabel
Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
@en
Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
@nl
P2093
P1433
P1476
Free Radicals Within the Antarctic Vortex: The Role of CFCs in Antarctic Ozone Loss
@en
P2093
D W Toohey
J G Anderson
P356
10.1126/SCIENCE.251.4989.39
P407
P577
1991-01-04T00:00:00Z