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Increasing importance of deposition of reduced nitrogen in the United StatesSources of bacteria in outdoor air across cities in the midwestern United States.Microfluidic electrochemical sensor for on-line monitoring of aerosol oxidative activityIntegrated membrane filters for minimizing hydrodynamic flow and filtering in microfluidic devices.Reply to Sun et al.: Deposition of organic nitrogen.Important fossil source contribution to brown carbon in Beijing during winter.Aerosol liquid water driven by anthropogenic nitrate: implications for lifetimes of water-soluble organic gases and potential for secondary organic aerosol formation.Enhanced role of transition metal ion catalysis during in-cloud oxidation of SO2.Determination of levoglucosan from smoke samples using microchip capillary electrophoresis with pulsed amperometric detection.Severe haze episodes and seriously polluted fog water in Ji'nan, China.Reply to Liu et al.: On the importance of US deposition of nitrogen dioxide, coarse particle nitrate, and organic nitrogen.Microscopic evaluation of trace metals in cloud droplets in an acid precipitation region.Organic matter in central California radiation fogs.High-sensitivity microchip electrophoresis determination of inorganic anions and oxalate in atmospheric aerosols with adjustable selectivity and conductivity detection.Using high time resolution aerosol and number size distribution measurements to estimate atmospheric extinction.Fragmentation analysis of water-soluble atmospheric organic matter using ultrahigh-resolution FT-ICR mass spectrometry.Particle size distributions of organic aerosol constituents during the 2002 Yosemite Aerosol Characterization Study.Aerosol species concentrations and source apportionment of ammonia at Rocky Mountain National Park.Residential Coal Combustion as a Source of Levoglucosan in China.Interfacing microchip electrophoresis to a growth tube particle collector for semicontinuous monitoring of aerosol composition.A seasonal nitrogen deposition budget for Rocky Mountain National Park.Deposition of reactive nitrogen during the Rocky Mountain Airborne Nitrogen and Sulfur (RoMANS) study.Impact of Front Range sources on reactive nitrogen concentrations and deposition in Rocky Mountain National Park.In-cloud sulfate addition to single particles resolved with sulfur isotope analysis during HCCT-2010Characterization of saccharides and associated usage in determining biogenic and biomass burning aerosols in atmospheric fine particulate matter in the North China PlainMeasurements and source apportionment of particle-associated polycyclic aromatic hydrocarbons in ambient air in Riyadh, Saudi ArabiaWintertime Residential Biomass Burning in Las Vegas, Nevada; Marker Components and Apportionment MethodsSecondary Organic Aerosol: A Comparison between Foggy and Nonfoggy DaysSpeciation of Mercury (II) and Methylmercury in Cloud and Fog WaterOptical, physical, and chemical properties of tar balls observed during the Yosemite Aerosol Characterization StudyAnalysis of anions in ambient aerosols by microchip capillary electrophoresisCloud physics and cloud water sampler comparison during FEBUKO
P50
Q28601885-2842A164-0056-4A17-A9A0-17ED139058F0Q33976320-DBF1B4B5-58F2-456C-85AC-7840AE0310C9Q36096500-3AEA99C9-6926-42A2-9BD8-E93BF06D2203Q36732586-9E583F68-9F95-4FC0-A6D6-FBD0DB267EB1Q37161502-C7E77123-9C5D-4569-936E-8C95FFF219EFQ37683960-62503778-354F-4E5E-8A4B-2CDD93B19F5BQ39134330-7882AA00-F261-44A5-B737-EB59A7E3646EQ39421452-D56F256A-7F40-41F7-B82D-E30F36130789Q39707707-03C58F57-928A-4B47-9573-804833CBA83AQ40201134-A7698CB2-80C0-4392-8F2A-E362C5BE5B2FQ42432322-9D7756AE-7810-47BF-9DCC-0827236713B3Q44965703-D136E884-49B8-4511-85D9-230555B80E96Q46061680-6B511FB0-D23F-4813-A45A-7ACCDEB728B5Q46151593-F4F0AE31-1C03-4FA3-9CE7-4CD05E051BC4Q46179966-C599DE37-B593-4B3D-B686-9F60C1A758F5Q46311775-657201E0-8163-4177-BC74-D5457A6EAEEBQ46401447-C29064C4-5880-4F34-8DD7-E88F6FD39BDCQ46958744-0D713AE4-8DC3-4890-A819-BDC600D4F7E8Q49818993-1D551D89-AB73-4B46-81A8-FBACADE9735FQ51562546-D8BA368B-B37F-423A-8F83-6E5C8F862814Q53318653-AB587EEA-41A5-4DA8-9ED6-3DB696A2FC37Q53494082-CF5DFC8F-659B-4A92-9E0E-CD276671618FQ55011502-4D2B4B00-4377-4A16-A838-129864652E07Q57600396-96596351-8827-49BA-9987-9503F683C61BQ58075147-A6F852AA-A194-40FE-8AF3-6B3448FC657DQ58381053-2A27E4D2-487A-4F67-901D-3DFCE718ABE6Q58381057-5E1C886E-6E9D-46FD-B1C4-69DA5D896F84Q58381086-CB6B9878-AD0A-463D-B738-3E002DAF82F7Q58381088-361095BF-8C20-4BE2-8639-82D32565AC2EQ58381090-94838274-51F6-46F0-AA59-0B334BFAB402Q58381102-664E556E-5972-46F9-83C1-A2F5E83BE08BQ59987537-64D3C0E8-1DD1-47BD-B128-58F3F69DB9A0
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Jeffrey L Collett
@ast
Jeffrey L Collett
@en
Jeffrey L Collett
@es
Jeffrey L Collett
@nl
Jeffrey L Collett
@sl
type
label
Jeffrey L Collett
@ast
Jeffrey L Collett
@en
Jeffrey L Collett
@es
Jeffrey L Collett
@nl
Jeffrey L Collett
@sl
prefLabel
Jeffrey L Collett
@ast
Jeffrey L Collett
@en
Jeffrey L Collett
@es
Jeffrey L Collett
@nl
Jeffrey L Collett
@sl
P1053
F-2862-2010
P106
P21
P31
P3829
P496
0000-0001-9180-508X