Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest

Using the 1-D atmospheric chemistry transport model SOSAA, we have investigated the atmospheric reactivity of a boreal forest ecosystem during the HUMPPA-COPEC-10 campaign (summer 2010, at SMEAR II in southern Finland). For the very first time, we present vertically resolved model simulations of the...

Full description

Bibliographic Details
Main Authors: Mogensen, D., Gierens, R., Crowley, J. N., Keronen, P., Smolander, S., Sogachev, A., Noelscher, A. C., Zhou, L., Kulmala, Markku, Tang, M. J., Williams, J., Boy, M.
Other Authors: Department of Physics, HENVI Hgin yliopiston ymp.tutk. ja ymp.o, Ecosystem processes (INAR Forest Sciences), Aerosol-Cloud-Climate -Interactions (ACCI)
Format: Article in Journal/Newspaper
Language:English
Published: COPERNICUS GESELLSCHAFT MBH 2016
Subjects:
CONTINENTAL BOUNDARY-LAYER
VOLATILE ORGANIC-COMPOUNDS
SCOTS PINE
ACTINIC FLUX
SULFURIC-ACID
SPECTRAL MEASUREMENTS
OXIDATION CAPACITY
SEASONAL-VARIATION
PHOTOCHEMICAL DATA
DATA ASSIMILATION
114 Physical sciences
Arctic
The Cryosphere
Online Access:http://hdl.handle.net/10138/161739
id ftunivhelsihelda:oai:helda.helsinki.fi:10138/161739
record_format openpolar
institution Open Polar
collection HELDA – University of Helsinki Open Repository
op_collection_id ftunivhelsihelda
language English
topic CONTINENTAL BOUNDARY-LAYER
VOLATILE ORGANIC-COMPOUNDS
SCOTS PINE
ACTINIC FLUX
SULFURIC-ACID
SPECTRAL MEASUREMENTS
OXIDATION CAPACITY
SEASONAL-VARIATION
PHOTOCHEMICAL DATA
DATA ASSIMILATION
114 Physical sciences
spellingShingle CONTINENTAL BOUNDARY-LAYER
VOLATILE ORGANIC-COMPOUNDS
SCOTS PINE
ACTINIC FLUX
SULFURIC-ACID
SPECTRAL MEASUREMENTS
OXIDATION CAPACITY
SEASONAL-VARIATION
PHOTOCHEMICAL DATA
DATA ASSIMILATION
114 Physical sciences
Mogensen, D.
Gierens, R.
Crowley, J. N.
Keronen, P.
Smolander, S.
Sogachev, A.
Noelscher, A. C.
Zhou, L.
Kulmala, Markku
Tang, M. J.
Williams, J.
Boy, M.
Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest
topic_facet CONTINENTAL BOUNDARY-LAYER
VOLATILE ORGANIC-COMPOUNDS
SCOTS PINE
ACTINIC FLUX
SULFURIC-ACID
SPECTRAL MEASUREMENTS
OXIDATION CAPACITY
SEASONAL-VARIATION
PHOTOCHEMICAL DATA
DATA ASSIMILATION
114 Physical sciences
description Using the 1-D atmospheric chemistry transport model SOSAA, we have investigated the atmospheric reactivity of a boreal forest ecosystem during the HUMPPA-COPEC-10 campaign (summer 2010, at SMEAR II in southern Finland). For the very first time, we present vertically resolved model simulations of the NO3 and O-3 reactivity (R) together with the modelled and measured reactivity of OH. We find that OH is the most reactive oxidant (R similar to 3 s(-1)) followed by NO3 (R similar to 0.07 s(-1)) and O-3 (R similar to 2 x 10 5 s(-1)). The missing OH reactivity was found to be large in accordance with measurements (similar to 65 %) as would be expected from the chemical subset described in the model. The accounted OH radical sinks were inorganic compounds (similar to 41 %, mainly due to reaction with CO), emitted monoterpenes (similar to 14 %) and oxidised biogenic volatile organic compounds (similar to 44 %). The missing reactivity is expected to be due to unknown biogenic volatile organic compounds and their photoproducts, indicating that the true main sink of OH is not expected to be inorganic compounds. The NO3 radical was found to react mainly with primary emitted monoterpenes (similar to 60 %) and inorganic compounds (similar to 37 %, including NO2). NO2 is, however, only a temporary sink of NO3 under the conditions of the campaign (with typical temperatures of 20-25 degrees C) and does not affect the NO3 concentration. We discuss the difference between instantaneous and steady-state reactivity and present the first boreal forest steady-state lifetime of NO3 (113 s). O-3 almost exclusively reacts with inorganic compounds (similar to 91 %, mainly NO, but also NO2 during night) and less with primary emitted sesquiterpenes (similar to 6 %) and monoterpenes (similar to 3 %). When considering the concentration of the oxidants investigated, we find that OH is the oxidant that is capable of removing organic compounds at a faster rate during daytime, whereas NO3 can remove organic molecules at a faster rate during ...
author2 Department of Physics
HENVI Hgin yliopiston ymp.tutk. ja ymp.o
Ecosystem processes (INAR Forest Sciences)
Aerosol-Cloud-Climate -Interactions (ACCI)
format Article in Journal/Newspaper
author Mogensen, D.
Gierens, R.
Crowley, J. N.
Keronen, P.
Smolander, S.
Sogachev, A.
Noelscher, A. C.
Zhou, L.
Kulmala, Markku
Tang, M. J.
Williams, J.
Boy, M.
author_facet Mogensen, D.
Gierens, R.
Crowley, J. N.
Keronen, P.
Smolander, S.
Sogachev, A.
Noelscher, A. C.
Zhou, L.
Kulmala, Markku
Tang, M. J.
Williams, J.
Boy, M.
author_sort Mogensen, D.
title Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest
title_short Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest
title_full Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest
title_fullStr Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest
title_full_unstemmed Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest
title_sort simulations of atmospheric oh, o-3 and no3 reactivities within and above the boreal forest
publisher COPERNICUS GESELLSCHAFT MBH
publishDate 2016
url http://hdl.handle.net/10138/161739
genre Arctic
The Cryosphere
genre_facet Arctic
The Cryosphere
op_relation 10.5194/acp-15-3909-2015
The authors are very grateful for the HUMPPA-COPEC-10 team from Helsinki University and MPI Mainz for providing data for which this study would not be possible. We would like to thank the following researchers personally: Christian Breitenberger, Birger Bohn, Horst Fischer, Rainer Konigstedt, Raoul Axinte, Uwe Parchatka and Zeinab Hosaynali-Beygi. D. Mogensen would like to personally thank Li Liao and Putian Zhou for technical help. Furthermore, we thank the Finnish Center of Excellence (FCoE), the Helsinki University Centre for Environment (HENVI) and the Cryosphere-Atmosphere Interactions in a Changing Arctic Climate (CRAICC) for financial support and the CSC - IT Center for Science Ltd for computational resources. Finally D. Mogensen would like to thank the Doctoral Program in Atmospheric Sciences (ATM-DP) for funding of doctoral studies and also the Danish Chemical Society for other financial support.
Mogensen , D , Gierens , R , Crowley , J N , Keronen , P , Smolander , S , Sogachev , A , Noelscher , A C , Zhou , L , Kulmala , M , Tang , M J , Williams , J & Boy , M 2015 , ' Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest ' , Atmospheric Chemistry and Physics , vol. 15 , no. 7 , pp. 3909-3932 . https://doi.org/10.5194/acp-15-3909-2015
ORCID: /0000-0001-5019-0904/work/32570874
ORCID: /0000-0002-2023-2461/work/29330860
84927733867
4a3d73d4-034d-42b6-8a6a-482aa7540e92
http://hdl.handle.net/10138/161739
000352957400017
op_rights cc_by
openAccess
info:eu-repo/semantics/openAccess
_version_ 1787421583794503680
spelling ftunivhelsihelda:oai:helda.helsinki.fi:10138/161739 2024-01-07T09:40:47+01:00 Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest Mogensen, D. Gierens, R. Crowley, J. N. Keronen, P. Smolander, S. Sogachev, A. Noelscher, A. C. Zhou, L. Kulmala, Markku Tang, M. J. Williams, J. Boy, M. Department of Physics HENVI Hgin yliopiston ymp.tutk. ja ymp.o Ecosystem processes (INAR Forest Sciences) Aerosol-Cloud-Climate -Interactions (ACCI) 2016-05-11T08:38:01Z 24 application/pdf http://hdl.handle.net/10138/161739 eng eng COPERNICUS GESELLSCHAFT MBH 10.5194/acp-15-3909-2015 The authors are very grateful for the HUMPPA-COPEC-10 team from Helsinki University and MPI Mainz for providing data for which this study would not be possible. We would like to thank the following researchers personally: Christian Breitenberger, Birger Bohn, Horst Fischer, Rainer Konigstedt, Raoul Axinte, Uwe Parchatka and Zeinab Hosaynali-Beygi. D. Mogensen would like to personally thank Li Liao and Putian Zhou for technical help. Furthermore, we thank the Finnish Center of Excellence (FCoE), the Helsinki University Centre for Environment (HENVI) and the Cryosphere-Atmosphere Interactions in a Changing Arctic Climate (CRAICC) for financial support and the CSC - IT Center for Science Ltd for computational resources. Finally D. Mogensen would like to thank the Doctoral Program in Atmospheric Sciences (ATM-DP) for funding of doctoral studies and also the Danish Chemical Society for other financial support. Mogensen , D , Gierens , R , Crowley , J N , Keronen , P , Smolander , S , Sogachev , A , Noelscher , A C , Zhou , L , Kulmala , M , Tang , M J , Williams , J & Boy , M 2015 , ' Simulations of atmospheric OH, O-3 and NO3 reactivities within and above the boreal forest ' , Atmospheric Chemistry and Physics , vol. 15 , no. 7 , pp. 3909-3932 . https://doi.org/10.5194/acp-15-3909-2015 ORCID: /0000-0001-5019-0904/work/32570874 ORCID: /0000-0002-2023-2461/work/29330860 84927733867 4a3d73d4-034d-42b6-8a6a-482aa7540e92 http://hdl.handle.net/10138/161739 000352957400017 cc_by openAccess info:eu-repo/semantics/openAccess CONTINENTAL BOUNDARY-LAYER VOLATILE ORGANIC-COMPOUNDS SCOTS PINE ACTINIC FLUX SULFURIC-ACID SPECTRAL MEASUREMENTS OXIDATION CAPACITY SEASONAL-VARIATION PHOTOCHEMICAL DATA DATA ASSIMILATION 114 Physical sciences Article publishedVersion 2016 ftunivhelsihelda 2023-12-14T00:10:17Z Using the 1-D atmospheric chemistry transport model SOSAA, we have investigated the atmospheric reactivity of a boreal forest ecosystem during the HUMPPA-COPEC-10 campaign (summer 2010, at SMEAR II in southern Finland). For the very first time, we present vertically resolved model simulations of the NO3 and O-3 reactivity (R) together with the modelled and measured reactivity of OH. We find that OH is the most reactive oxidant (R similar to 3 s(-1)) followed by NO3 (R similar to 0.07 s(-1)) and O-3 (R similar to 2 x 10 5 s(-1)). The missing OH reactivity was found to be large in accordance with measurements (similar to 65 %) as would be expected from the chemical subset described in the model. The accounted OH radical sinks were inorganic compounds (similar to 41 %, mainly due to reaction with CO), emitted monoterpenes (similar to 14 %) and oxidised biogenic volatile organic compounds (similar to 44 %). The missing reactivity is expected to be due to unknown biogenic volatile organic compounds and their photoproducts, indicating that the true main sink of OH is not expected to be inorganic compounds. The NO3 radical was found to react mainly with primary emitted monoterpenes (similar to 60 %) and inorganic compounds (similar to 37 %, including NO2). NO2 is, however, only a temporary sink of NO3 under the conditions of the campaign (with typical temperatures of 20-25 degrees C) and does not affect the NO3 concentration. We discuss the difference between instantaneous and steady-state reactivity and present the first boreal forest steady-state lifetime of NO3 (113 s). O-3 almost exclusively reacts with inorganic compounds (similar to 91 %, mainly NO, but also NO2 during night) and less with primary emitted sesquiterpenes (similar to 6 %) and monoterpenes (similar to 3 %). When considering the concentration of the oxidants investigated, we find that OH is the oxidant that is capable of removing organic compounds at a faster rate during daytime, whereas NO3 can remove organic molecules at a faster rate during ... Article in Journal/Newspaper Arctic The Cryosphere HELDA – University of Helsinki Open Repository

Similar Items