Multi-stage open peer review: scientific evaluation integrating the strengths of traditional peer review with the virtues of transparency and self-regulationMetaproteomic analysis of atmospheric aerosol samplesQuantitative DNA Analyses for Airborne Birch PollenHigh potential for weathering and climate effects of non-vascular vegetation in the Late OrdovicianBiological soil crusts accelerate the nitrogen cycle through large NO and HONO emissions in drylandsAnalysis of large oxygenated and nitrated polycyclic aromatic hydrocarbons formed under simulated diesel engine exhaust conditions (by compound fingerprints with SPE/LC-API-MS)Chemical exposure-response relationship between air pollutants and reactive oxygen species in the human respiratory tractPhenyl-modified reversed-phase liquid chromatography coupled to atmospheric pressure chemical ionization mass spectrometry: a universal method for the analysis of partially oxidized aromatic hydrocarbons.Analysis of nitrated polycyclic aromatic hydrocarbons by liquid chromatography with fluorescence and mass spectrometry detection: air particulate matter, soot, and reaction product studies.Aerosol Chemistry Resolved by Mass Spectrometry: Linking Field Measurements of Cloud Condensation Nuclei Activity to Organic Aerosol Composition.Global distribution of particle phase state in atmospheric secondary organic aerosolsAir Pollution and Climate Change Effects on Allergies in the Anthropocene: Abundance, Interaction, and Modification of Allergens and Adjuvants.Nitration of the egg-allergen ovalbumin enhances protein allergenicity but reduces the risk for oral sensitization in a murine model of food allergy.Size dependence of phase transitions in aerosol nanoparticles.Bioprecipitation: a feedback cycle linking earth history, ecosystem dynamics and land use through biological ice nucleators in the atmosphere.Gas uptake and chemical aging of semisolid organic aerosol particles.Nitrous oxide and methane emissions from cryptogamic covers.Satellite retrieval of cloud condensation nuclei concentrations by using clouds as CCN chambers.Atmospheric aerosols: composition, transformation, climate and health effects.High diversity of fungi in air particulate matter.Reactive nitrogen chemistry in aerosol water as a source of sulfate during haze events in ChinaHazardous components and health effects of atmospheric aerosol particles: reactive oxygen species, soot, polycyclic aromatic compounds and allergenic proteins.Nitration of the birch pollen allergen Bet v 1.0101: efficiency and site-selectivity of liquid and gaseous nitrating agents.Multiphase chemistry at the atmosphere-biosphere interface influencing climate and public health in the anthropocene."What We Breathe Impacts Our Health: Improving Understanding of the Link between Air Pollution and Health".Ice-nucleating bacteria control the order and dynamics of interfacial waterPolycyclic aromatic hydrocarbons in urban air particulate matter: decadal and seasonal trends, chemical degradation, and sampling artifacts.Enzyme immunoassays for the investigation of protein nitration by air pollutants.Glass transition and phase state of organic compounds: dependency on molecular properties and implications for secondary organic aerosols in the atmosphere.Protein nitration by polluted air.Nitration enhances the allergenic potential of proteins.Genotoxicity of total and fractionated extractable organic matter in fine air particulate matter from urban Guangzhou: comparison between haze and nonhaze episodes.Ozone uptake on glassy, semi-solid and liquid organic matter and the role of reactive oxygen intermediates in atmospheric aerosol chemistry.Quantification of nitrotyrosine in nitrated proteins.Protein Cross-Linking and Oligomerization through Dityrosine Formation upon Exposure to Ozone.The diesel exhaust component pyrene induces expression of IL-8 but not of eotaxin.Arctic ozone loss due to denitrificationRadial diffusion and penetration of gas molecules and aerosol particles through laminar flow reactors, denuders, and sampling tubes.Multiphase chemical kinetics of OH radical uptake by molecular organic markers of biomass burning aerosols: humidity and temperature dependence, surface reaction, and bulk diffusion.Mass accommodation of water: bridging the gap between molecular dynamics simulations and kinetic condensation models
P50
Q21129452-26862C75-FA38-40F1-BB1C-C0D2F1F232D1Q28388285-D69C21AE-8CC9-43A3-B4F6-278FE605530DQ28392046-8AAB8B71-D4A9-45F5-A521-C83A13AEE669Q28596467-5C660D4B-E2F2-483E-AF8E-2E15A947E5CFQ28603681-1DB4B446-A04F-413B-8F09-95AA4BF23E53Q28757564-C907F5A8-D815-4CFC-895E-CF3FDAA8C522Q28831072-E7472666-BB32-4882-B29C-0A2C1A78611BQ33423122-4A10B56E-96A5-4859-B325-C0FD8E39E0D1Q33430818-72021F73-57A4-4E1D-8687-712C5006AC92Q33468925-C907E6EF-0C23-4FB8-AC62-F605859171AFQ33628888-51C0AEEC-623A-41FA-B131-053D09242CB4Q33752095-14F427BE-C08C-4CD1-AB75-B6DA43BE7205Q33769668-CD5C5067-9728-4C1E-9D1E-EADC60B1EDBBQ35023057-4E91FD36-4C13-4556-872F-186F9E55E442Q35084676-46C68E38-EF38-47BC-9EB1-618CB161657DQ35090948-D0AD810E-D440-420A-984C-8AADA3881572Q35685526-D58A30FA-3F72-4D90-A507-9BB8F68E7603Q35946358-30271206-A089-4AD1-B17B-53206A8F3F7DQ36319217-4E845320-F1FF-49BF-B573-04909345A245Q37293115-F8516254-CEFC-40B9-9217-D69A20E247E6Q37524862-025F2402-42B7-436D-8A4E-257B65238C64Q37980880-64AC7F38-0F55-46D9-AE30-95D8AA61BAAAQ38257664-A0091A0D-2A34-48EA-95EE-3BE82FB97E3FQ38412918-B8BE9824-C015-462B-98B1-9A910FF405D0Q38890749-4FDB0E45-F250-4A13-B7B6-DC2304B74739Q39137402-94D66363-EB13-48EA-B74B-567965475B72Q39655567-4B5A2026-9A4E-4D42-8124-75F53EDB4EA7Q39656584-3FA9C3AA-31CF-4EC4-9D94-BCCD8D160251Q39698163-E8900A2D-F159-4E1F-8F54-FE7F734BD438Q39712939-38EE4FB0-D493-473B-B873-742CC5F3DD95Q39766782-2D1562C8-A232-4843-B4B0-930AD17A8E4AQ39826506-BE4F8063-D271-45BC-8D30-2C29D1806DD7Q39837865-14317F91-1267-4744-A1E8-8F70410028D8Q40059087-52B4E2DA-1F0C-40DD-B211-1AD0B75253A5Q40628046-D3017B71-BF11-4C5B-9ED8-6E6B736A304AQ40639344-BF891582-7BD0-49B9-9E13-033B20373A38Q40820279-690E50F7-3D79-44DC-B41C-ADA60FC89A8CQ41284864-42BE787B-F52A-4C75-8C09-E2F5E2FB9ABCQ41429088-2A42CA2A-58A8-4FCC-BB92-DFA1AEF79FEFQ42087229-7234DF26-2D00-40F4-AA47-7B5907594AF1
P50
description
Austria keemik
@et
Austrian chemist
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Austrian chemist
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Austrian chemist
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austerriksk kjemikar
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aŭstra kemiisto
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ceimiceoir Ostarach
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chimist austriac
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chimiste autrichien
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cimiciste osteraices
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
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altLabel
Ulrich Poschl Ulrich Poeschl
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prefLabel
Ulrich Pöschl
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Ulrich Pöschl
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Ulrich Pöschl
@da
Ulrich Pöschl
@de
Ulrich Pöschl
@en
Ulrich Pöschl
@es
Ulrich Pöschl
@fr
Ulrich Pöschl
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Ulrich Pöschl
@nb
Ulrich Pöschl
@nl
P214
P227
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P21
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0000 0000 2063 9590
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