Impact of evolving isoprene mechanisms on simulated formaldehyde: An inter-comparison supported by in situ observations from SENEX

Atmospheric Environment

Volumn 164, Issue , 2017, Pages 325-336

  Marvin, Margaret R ^a   Wolfe, Glenn M ^b,c   Salawitch, Ross J ^a,d   Canty, Timothy P ^d   Roberts, Sandra J ^a   Travis, Katherine R ^e,f   Aikin, Kenneth C ^g,h   de Gouw, Joost A ^g,h   Graus, Martin ^g,h,k   Hanisco, Thomas F ^c   Holloway, John S ^g,h   Hübler, Gerhard ^g,h   Kaiser, Jennifer ^e   Keutsch, Frank N ^e,i   Peischl, Jeff ^g,h   Pollack, Ilana B ^j   Roberts, James M ^h   Ryerson, Thomas B ^h   Veres, Patrick R ^g,h   Warneke, Carsten ^g,h  

^a UNIVERSITY OF MARYLAND   (United States)

^b UNIVERSITY OF MARYLAND BALTIMORE COUNTY   (United States)

^c NASA GODDARD SPACE FLIGHT CENTER   (United States)

^d Bldg 142   (United States)

^e HARVARD UNIVERSITY   (United States)

^f HARVARD UNIVERSITY   (United States)

^g UNIVERSITY OF COLORADO   (United States)

^h NOAA EARTH SYSTEM RESEARCH LABORATORY   (United States)

ⁱ HARVARD UNIVERSITY   (United States)

^j Engineering Research Center and Hydraulics Laboratory   (United States)

^k UNIVERSITY OF INNSBRUCK   (Austria)

more..

Author keywords

Air quality; Box model; Formaldehyde; Gas phase chemical mechanisms; Isoprene; SENEX

Indexed keywords

AIR QUALITY; CARBON; COMPUTATIONAL EFFICIENCY; FORMALDEHYDE; MIXING; OXIDATION; OZONE;

AIR QUALITY MODELING; BOX MODELS; CARBON BOND MECHANISMS; CHEMICAL MECHANISM; MASTER CHEMICAL MECHANISM; PHOTOCHEMICAL BOX MODEL; SATELLITE OBSERVATIONS; SENEX;

ISOPRENE;

FORMALDEHYDE; ISOPRENE; OZONE;

AIR QUALITY; EOS; FORMALDEHYDE; IN SITU MEASUREMENT; ISOPRENE; MIXING RATIO; OXIDATION; OZONE; PHOTOCHEMISTRY;

AIR QUALITY; AIRCRAFT; ARTICLE; CONTROLLED STUDY; GAS; OXIDATION; PHOTOCHEMISTRY; PRIORITY JOURNAL; SIMULATION; UNCERTAINTY;

EID: 85020766028     PISSN: 13522310     EISSN: 18732844     Source Type: Journal    
DOI: 10.1016/j.atmosenv.2017.05.049     Document Type: Article

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