%0 Journal Article %1 Holloway2000 %A Holloway, T %A Levy, H %A Kasibhatla, P %C 2000 FLORIDA AVE NW, WASHINGTON, DC 20009 USA %D 2000 %I AMER GEOPHYSICAL UNION %J Journal of Geophysical Research-Atmospheres %K %N D10 %P 12123--12147 %T Global distribution of carbon monoxide %U http://www.agu.org/journals/jd/v105/iD10/1999JD901173/ %V 105 %X This study explores the evolution and distribution of carbon monoxide (CO) using the National Oceanic and Atmospheric Administration (NOAA) Geophysical Fluid Dynamics Laboratory three-dimensional global chemical transport model (GFDL GCTM). The work aims to gain an improved understanding of the global carbon monoxide budget, specifically focusing on the contribution of each of the four source terms to the seasonal variability of CO. The sum of all CO sources in the model is 2.5 Pg CO/yr (1 Pg = 10(3) Tg) including fossil fuel use (300 Tg CO /yr), biomass burning (748 Tg CO/yr), oxidation of biogenic hydrocarbons (683 Tg CO/yr), and methane oxidation (760 Tg CO/yr). The main sink for CO is destruction by the hydroxyl radical, and we assume a hydroxyl distribution based on three-dimensional monthly varying fields given by Spivakovsky et al. 1990, but we increase this field by 15\% uniformly to agree with a methyl chloroform lifetime of 4.8 years Prinn et al., 1995. Our simulation produces a carbon monoxide field that agrees well with available measurements from the NOAA/Climate Monitoring and Diagnostics Laboratory global cooperative flask sampling network and from the Jungfraujoch observing station of the Swiss Federal Laboratories for Materials Testing and Research (EMPA) (93\% of seasonal-average data points agree within +/-25\%) and flight data from measurement campaigns of the NASA Global Tropospheric Experiment (79\% of regional-average data points agree within +/-25\%). For all 34 ground-based measurement sites we have calculated the percentage contribution of each CO source term to the total model-simulated distribution and examined how these contributions vary seasonally due to transport, changes in OH concentration, and seasonality of emission sources. CO from all four sources contributes to the total magnitude of CO in all regions. Seasonality, however, is usually governed by the transport and destruction by OH of CO emitted by fossil fuel and/or biomass burning. The sensitivity to the hydroxyl field varies spatially, with a 30\% increase in OH yielding decreases in CO ranging from 4-23\%, with lower sensitivities near emission regions where advection acts as a strong local sink. The lifetime of CO varies from 10 days over summer continental regions to well over a year at the winter poles, where we define lifetime as the turnover time in the troposphere due to reaction with OH.

@article{Holloway2000, abstract = {This study explores the evolution and distribution of carbon monoxide (CO) using the National Oceanic and Atmospheric Administration (NOAA) Geophysical Fluid Dynamics Laboratory three-dimensional global chemical transport model (GFDL GCTM). The work aims to gain an improved understanding of the global carbon monoxide budget, specifically focusing on the contribution of each of the four source terms to the seasonal variability of CO. The sum of all CO sources in the model is 2.5 Pg CO/yr (1 Pg = 10(3) Tg) including fossil fuel use (300 Tg CO /yr), biomass burning (748 Tg CO/yr), oxidation of biogenic hydrocarbons (683 Tg CO/yr), and methane oxidation (760 Tg CO/yr). The main sink for CO is destruction by the hydroxyl radical, and we assume a hydroxyl distribution based on three-dimensional monthly varying fields given by Spivakovsky et al. {[}1990], but we increase this field by 15\% uniformly to agree with a methyl chloroform lifetime of 4.8 years {[}Prinn et al., 1995]. Our simulation produces a carbon monoxide field that agrees well with available measurements from the NOAA/Climate Monitoring and Diagnostics Laboratory global cooperative flask sampling network and from the Jungfraujoch observing station of the Swiss Federal Laboratories for Materials Testing and Research (EMPA) (93\% of seasonal-average data points agree within +/-25\%) and flight data from measurement campaigns of the NASA Global Tropospheric Experiment (79\% of regional-average data points agree within +/-25\%). For all 34 ground-based measurement sites we have calculated the percentage contribution of each CO source term to the total model-simulated distribution and examined how these contributions vary seasonally due to transport, changes in OH concentration, and seasonality of emission sources. CO from all four sources contributes to the total magnitude of CO in all regions. Seasonality, however, is usually governed by the transport and destruction by OH of CO emitted by fossil fuel and/or biomass burning. The sensitivity to the hydroxyl field varies spatially, with a 30\% increase in OH yielding decreases in CO ranging from 4-23\%, with lower sensitivities near emission regions where advection acts as a strong local sink. The lifetime of CO varies from 10 days over summer continental regions to well over a year at the winter poles, where we define lifetime as the turnover time in the troposphere due to reaction with OH.}, added-at = {2009-06-08T21:16:06.000+0200}, address = {2000 FLORIDA AVE NW, WASHINGTON, DC 20009 USA}, affiliation = {Holloway, T (Reprint Author), Princeton Univ, Atmospher \& Ocean Sci Program, Princeton, NJ 08544 USA. Princeton Univ, Atmospher \& Ocean Sci Program, Princeton, NJ 08544 USA. Geophys Fluid Dynam Lab, Princeton, NJ 08542 USA. Duke Univ, Nicholas Sch Environm, Durham, NC 27708 USA.}, author = {Holloway, T and Levy, H and Kasibhatla, P}, biburl = {https://www.bibsonomy.org/bibtex/22377141347ea052f13f1e822ffa39067/claas}, cited-references = {{*}EIA, 1997, DOEEIA048497. {*}EPA, 1997, EPA454R97011 RES TRI. {*}IPCC, 1992, CLIM CHANG 1992 SUPP. ALLEN DJ, 1996, J GEOPHYS RES-ATMOS, V101, P28655. ANDREAE MO, 1991, GLOBAL BIOMASS BURNI, P3. BAKWIN PS, 1994, GEOPHYS RES LETT, V21, P433. BALTENSPERGER U, 1997, J GEOPHYS RES-ATMOS, V102, P19707. BATES TS, 1995, J GEOPHYS RES-ATMOSP, V100, P23093. BENKOVITZ CM, 1996, J GEOPHYS RES-ATMOS, V101, P29239. BERNTSEN TK, 1997, J GEOPHYS RES-ATMOS, V102, P21239. BLAKE NJ, 1996, J GEOPHYS RES-ATMOS, V101, P24151. BRASSEUR GP, 1998, J GEOPHYS RES-ATMOS, V103, P28265. CHAMEIDES WL, 1994, SCIENCE, V264, P74. CHAPPELLAZ J, 1997, J GEOPHYS RES-ATMOS, V102, P15987. CRUTZEN PJ, 1990, SCIENCE, V250, P1669. DLUGOKENCKY EJ, 1994, J GEOPHYS RES-ATMOS, V99, P17021. FISHMAN J, 1996, J GEOPHYS RES-ATMOS, V101, P23865. FUELBERG HE, 1999, J GEOPHYS RES-ATMOS, V104, P5585. GALANTER MK, 2000, IN PRESS J GEOPHYS R. GUENTHER, 1995, J GEOPHYS RES, V100, P8873. HAO WM, 1994, GLOBAL BIOGEOCHEM CY, V8, P495. HARRISS RC, 1988, J GEOPHYS RES, V93, P1351. HARRISS RC, 1990, J GEOPHYS RES, V95, P16721. HARRISS RC, 1992, J GEOPHYS RES, V97, P16383. HARRISS RC, 1994, J GEOPHYS RES, V99, P1635. HAUGLUSTAINE DA, 1998, J GEOPHYS RES-ATMOS, V103, P28291. HOELL JM, 1990, J GEOPHYS RES-ATMOS, V95, P10047. HOELL JM, 1993, J GEOPHYS RES-ATMOSP, V98, P23291. HOELL JM, 1996, J GEOPHYS RES-ATMOS, V101, P1641. HOELL JM, 1997, J GEOPHYS RES-ATMOS, V102, P28223. KANAKIDOU, 1999, CHEMOSPHERE GLOBAL C, V1, P263. KASIBHATLA P, 1996, J GEOPHYS RES-ATMOS, V101, P29305. KASIBHATLA P, 1997, J GEOPHYS RES-ATMOS, V102, P3737. KLONECKI A, 1997, J GEOPHYS RES-ATMOS, V102, P21221. KLONECKI AA, 1999, THESIS PRINCETON U P. LEVY H, 1991, GLOBAL BIOMASS BURNI, P363. LEVY H, 1997, GEOPHYS RES LETT, V24, P791. LEVY H, 1999, J GEOPHYS RES-ATMOS, V104, P26279. MAHLMAN JD, 1978, J ATMOS SCI, V35, P1340. MANABE S, 1974, J ATMOS SCI, V31, P4383. MANABE S, 1975, J GEOPHYS RES, V80, P1617. MCKEE DJ, 1993, TROPOSPHERIC OZONE H. MIYOSHI A, 1994, J GEOPHYS RES-ATMOS, V99, P18779. MULLER JF, 1995, J GEOPHYS RES, V100, P44516. NOVELLI PC, 1992, J GEOPHYS RES-ATMOSP, V97, P20731. OLIVIER JGJ, 1994, ENVIRON MONIT ASSESS, V31, P93. OLSON JR, 1999, J GEOPHYS RES-ATMOS, V104, P5865. PINTO JP, 1983, J GEOPHYS RES, V88, P3691. PRINN RG, 1995, SCIENCE, V269, P187. RICHARDSON JL, 1994, THESIS GA I TECHNOL. SACHSE GW, 1988, J GEOPHYS RES, V93, P1422. SANHUEZA E, 1998, TELLUS B, V50, P51. SAYLOR RD, 1991, AIR POLLUTION MODELL, V8. SEINFELD JH, 1986, ATMOSPHERIC CHEM PHY. SPIVAKOVSKY CM, 1990, J GEOPHYS RES-ATMOSP, V95, P18441. STREETS DG, 1998, ENERGY, V23, P1029. TIE XX, 1992, ATMOS ENVIRON A-GEN, V26, P125. VANAARDENNE JA, 1999, ATMOS ENVIRON, V33, P633. WANG YH, 1998, J GEOPHYS RES-ATMOS, V103, P10727. WARNECK P, 1988, CHEM NATURAL ATMOSPH, V41. YIENGER J, 1999, J GEOPHYS RES, V103, P3655. ZELLWEGER C, 2000, IN PRESS J GEOPHYS R.}, doc-delivery-number = {319WL}, file = {Holloway2000.pdf:Holloway2000.pdf:PDF}, interhash = {54ffbed75547b2ace44f63bea3a15696}, intrahash = {2377141347ea052f13f1e822ffa39067}, issn = {0747-7309}, journal = {Journal of Geophysical Research-Atmospheres}, journal-iso = {J. Geophys. Res.-Atmos.}, keywords = {}, keywords-plus = {CHEMICAL-TRANSPORT MODEL; GENERAL-CIRCULATION MODEL; ATMOSPHERIC METHANE; TROPOSPHERIC OZONE; DRY SEASON; CHEMISTRY; EMISSIONS; CO; OH; SIMULATION}, language = {English}, month = {MAY 27}, number = {D10}, number-of-cited-references = {62}, pages = {12123--12147}, publisher = {AMER GEOPHYSICAL UNION}, subject-category = {Meteorology \& Atmospheric Sciences}, times-cited = {72}, timestamp = {2009-06-08T21:16:06.000+0200}, title = {Global distribution of carbon monoxide}, type = {Article}, unique-id = {ISI:000087366600003}, url = {http://www.agu.org/journals/jd/v105/iD10/1999JD901173/}, volume = 105, year = 2000 }