%0 Journal Article %1 Emmons:1997p188 %A Emmons, L %A Carroll, M %A Hauglustaine, D %A Brasseur, G %A Atherton, C %A Penner, J %A Sillman, S %A Levy, H %A Rohrer, F %A Wauben, W %A VanVelthoven, P %A Wang, Y %A Jacob, D %A Bakwin, P %A Dickerson, R %A Doddridge, B %A Gerbig, C %A Honrath, R %A Hubler, G %A Jaffe, D %A Kondo, Y %A Munger, J %A Torres, A %A VolzThomas, A %D 1997 %J Atmospheric Environment %K imported %N 12 %P 1851--1904 %T Climatologies of NOx and NOy: A comparison of data and models %U http://links.isiglobalnet2.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=mekentosj&SrcApp=Papers&DestLinkType=FullRecord&DestApp=WOS&KeyUT=A1997WU83500009 %V 31 %X Climatologies of tropospheric NOx(NO + NO2) and NOy (total reactive nitrogen: NOx + NO3 + 2 x N2O5 + HNO2 + HNO3 + HNO4 + ClONO2 + PAN (peroxyacetylnitrate) + other organic nitrates) have been compiled from data previously published and, in most cases, publicly archived. Emphasis has been on non-urban measurements, including rural and remote ground sites, as well as aircraft data. Although the distribution of data is sparse, a compilation in this manner can begin to provide an understanding of the spatial and temporal distributions of these reactive nitrogen species. The cleanest measurements in the boundary layer are in Alaska, northern Canada and the eastern Pacific, with median NO mixing ratios below 10 pptv, NOx below 50 pptv, and NOy below 300 pptv. The highest NO values (greater than 1 ppbv) were found in eastern North America and Europe, with correspondingly high NOy (similar to 5 ppbv). A significantly narrower range of concentrations is seen in the free troposphere, particularly at 3-6 km, with NO typically about 10 pptv in the boreal summer. NO increases with altitude to similar to 100 pptv at 9-12 km, whereas NOy does not show a trend with altitude, but varies between 100 and 1000 pptv. Decreasing mixing ratios eastward of the Asian and North American continents are seen in all three species at all altitudes. Model-generated climatologies of NOx and NOy from six chemical transport models are also presented and are compared with observations in the boundary layer and the middle troposphere for summer and winter. These comparisons test our understanding of the chemical and transport processes responsible for these species distributions. Although the model results show differences between them, and disagreement with observations, none are systematically different for all seasons and altitudes. Some of the differences between the observations and model results may likely be attributed to the specific meteorological conditions at the time that measurements were made differing from the model meteorology, which is either climatological how from GCMs or actual meteorology for an arbitrary year. Differences in emission inventories, and convection and washout schemes in the models will also affect the calculated NOx and NOy distributions. (C) 1997 Elsevier Science Ltd.

@article{Emmons:1997p188, abstract = {Climatologies of tropospheric NOx(NO + NO2) and NOy (total reactive nitrogen: NOx + NO3 + 2 x N2O5 + HNO2 + HNO3 + HNO4 + ClONO2 + PAN (peroxyacetylnitrate) + other organic nitrates) have been compiled from data previously published and, in most cases, publicly archived. Emphasis has been on non-urban measurements, including rural and remote ground sites, as well as aircraft data. Although the distribution of data is sparse, a compilation in this manner can begin to provide an understanding of the spatial and temporal distributions of these reactive nitrogen species. The cleanest measurements in the boundary layer are in Alaska, northern Canada and the eastern Pacific, with median NO mixing ratios below 10 pptv, NOx below 50 pptv, and NOy below 300 pptv. The highest NO values (greater than 1 ppbv) were found in eastern North America and Europe, with correspondingly high NOy (similar to 5 ppbv). A significantly narrower range of concentrations is seen in the free troposphere, particularly at 3-6 km, with NO typically about 10 pptv in the boreal summer. NO increases with altitude to similar to 100 pptv at 9-12 km, whereas NOy does not show a trend with altitude, but varies between 100 and 1000 pptv. Decreasing mixing ratios eastward of the Asian and North American continents are seen in all three species at all altitudes. Model-generated climatologies of NOx and NOy from six chemical transport models are also presented and are compared with observations in the boundary layer and the middle troposphere for summer and winter. These comparisons test our understanding of the chemical and transport processes responsible for these species distributions. Although the model results show differences between them, and disagreement with observations, none are systematically different for all seasons and altitudes. Some of the differences between the observations and model results may likely be attributed to the specific meteorological conditions at the time that measurements were made differing from the model meteorology, which is either climatological how from GCMs or actual meteorology for an arbitrary year. Differences in emission inventories, and convection and washout schemes in the models will also affect the calculated NOx and NOy distributions. (C) 1997 Elsevier Science Ltd.}, added-at = {2010-06-22T19:38:37.000+0200}, affiliation = {Emmons, LK Univ Michigan,Dept Atmospher Ocean {\&} Space Sci,Ann Arbor,Mi 48109 Natl Ctr Atmospher Res,Boulder,Co 80307 Lawrence Livermore Natl Lab,Livermore,Ca Princeton Univ,Noaa,Geophys Fluid Dynam Lab,Princeton,Nj 08542 Kfa Julich Gmbh,Forschungszentrum,Icg,Julich,Germany Royal Netherlands Meteorol Inst,Nl-3730 Ae De Bilt,Netherlands Harvard Univ,Cambridge,Ma 02138 Noaa,Climate Monitoring {\&} Diagnost Lab,Boulder,Co 80303 Univ Maryland,College Pk,Md 20742 Michigan Technol Univ,Houghton,Mi 49931 Noaa,Aeron Lab,Boulder,Co 80303 Univ Alaska,Fairbanks,Ak 99701 Nagoya Univ,Nagoya,Aichi,Japan Nasa,Wallops Flight Facil,Wallops Isl,Va}, author = {Emmons, L and Carroll, M and Hauglustaine, D and Brasseur, G and Atherton, C and Penner, J and Sillman, S and Levy, H and Rohrer, F and Wauben, W and VanVelthoven, P and Wang, Y and Jacob, D and Bakwin, P and Dickerson, R and Doddridge, B and Gerbig, C and Honrath, R and Hubler, G and Jaffe, D and Kondo, Y and Munger, J and Torres, A and VolzThomas, A}, biburl = {https://www.bibsonomy.org/bibtex/265fa5f1bc876af3accfbb667c92aca3a/gsmith}, date-added = {2010-03-10 16:47:18 -0500}, date-modified = {2010-03-10 16:48:22 -0500}, interhash = {c038af192f06575b92d96ba9cb5b1203}, intrahash = {65fa5f1bc876af3accfbb667c92aca3a}, journal = {Atmospheric Environment}, keywords = {imported}, label = {rec-number 1627}, local-url = {file://localhost/Users/geoffreysmith/Documents/Papers/Atmospheric%20Environment/1997/Atmospheric%20Environment,%2031,%201851-1904%201997.pdf}, month = Jun, note = {Wu835 Times Cited:83 Cited References Count:176}, number = 12, pages = {1851--1904}, pmid = {A1997WU83500009}, rating = {0}, timestamp = {2010-06-22T19:39:37.000+0200}, title = {Climatologies of NOx and NOy: A comparison of data and models}, uri = {papers://E88B624E-D406-46FF-9D95-BB9C1AAE3FDC/Paper/p188}, url = {http://links.isiglobalnet2.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=mekentosj&SrcApp=Papers&DestLinkType=FullRecord&DestApp=WOS&KeyUT=A1997WU83500009}, volume = 31, year = 1997 }