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2017 | OriginalPaper | Chapter

8. Atmosphärische Spurengase

Authors : Walter Roedel, Thomas Wagner

Published in: Physik unserer Umwelt: Die Atmosphäre

Publisher: Springer Berlin Heidelberg

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Zusammenfassung

In diesem Kapitel wird ein Überblick über wichtige atmosphärische Spurengase, ausgewählte atmosphärische Reaktionszyklen sowie wichtige physikalisch-chemische Phänomene wie das stratosphärsiche Ozonloch oder Sommersmog gegeben.

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Anderson JG (1975) The absolute concentration of O(3P) in the earth\9s stratosphere. Geophys Res Lett 2:231–234CrossRef

Anderson JG, Margitan JJ, Stedman DH (1977) Atomic chlorine and the chlorine monoxid radical in the stratosphere: Three in situ observations. Science 198:501–503CrossRef

Archer D (2007) Methane hydrate stability and anthropogenic climate change. Biogeosciences 4:521–544CrossRef

Arnold F, Knop G (1989) Stratospheric nitric acid vapour measurements in the cold arctic vortex: Implications for nitric acid condensation. Nature (London) 338:746–749CrossRef

Bacastow RB, Keeling CD, Whorf TP (1985) Seasonal amplitude increase in atmospheric CO₂ concentrations at Mauna Loa, Hawai, 1959–1982. J Geophys Res 90:10529–10540CrossRef

Barnola JM, Raynaud D, Korotkevich YS, Lorius C (1987) Vostok ice core provides 160,000-year record of atmospheric CO₂. Nature (London) 329:408–414CrossRef

Beirle S (2006) Average tropospheric NO₂ distribution derived from SCIAMACHY observations. http://joseba.mpch-mainz.mpg.de/no2_nad.htm. Zugegriffen: 20. Febr. 2017

Boden T, Marland G, Andres R (2011) Global CO₂ emissions from fossil-fuel burning, cement manufacture, and gas flaring: 1751–2008. Oak Ridge National Laboratory, U. S. Department of Energy, Carbon Dioxide Information Analysis Center, Oak Ridge, TN, USA., https://doi.org/10.3334/CDIAC/00001_V2011, http://cdiac.ornl.gov/trends/emis/overview_2008.html. Zugegriffen: 10. Nov. 2011.

Bojkov RD, Zerefos CS, Balis DS, Ziomas IG, Bais AF (1993) Record low total ozone during northern winters of 1992 and 1993. Geophys Res Lett 20:1351–1354CrossRef

Borsdorff T, Tol P, Williams JE, de Laat J, aan de Brugh J, Nédélec P, Aben I, Landgraf J (2016) Carbon monoxide total columns from SCIAMACHY 2.3 µm atmospheric reflectance measurements: towards a full-mission data product (2003–2012). Atmos Meas Tech 9:227–248. https://doi.org/10.5194/amt-9-227-2016CrossRef

Borsdorff T, aan de Brugh J, Hu H, Nédélec P, Aben I, Landgraf J (2017) Carbon monoxide column retrieval for clear-sky and cloudy atmospheres: a full-mission data set from SCIAMACHY 2.3 µm reflectance measurements. Atmos Meas Tech Discuss. https://doi.org/10.5194/amt-2016-355

Bradshaw J, Davis D, Grodzinsky G, Smyth S, Newell R, Sandholm S, Liu S (2000) Observed distribution of nitrogen oxides in the remote free troposphere from the NASA global tropospheric experiment programs. Rev Geophys 38:611–116CrossRef

Broecker WS, Takahashi T, Simpson HJ, Peng TH (1979) Fate of fossil carbon dioxide and the global carbon budget. Science 206:409–418CrossRef

Brunner D, Staehelin J, Maeder JA, Wohltmann I, Bodeker GE (2006) Variability and trends in total and vertically resolved stratospheric ozone based on the CATO ozone data set. Atmos Chem Phys 6:4985–5008. https://doi.org/10.5194/acp-6-4985-2006CrossRef

Carslaw KS, Luo PB, Clegg SL, Peter T, Brimblecombe P, Crutzen PJ (1994) Stratospheric aerosol growth and HNO₃ gas phase depletion from coupled HNO₃ and water uptake by liquid particles. Geophys Res Lett 21:2479–2482CrossRef

Chapman S (1930) A theory of upper atmospheric ozone. Quart J R Meteorol Soc 3: 103–125

Chappellaz J, Barnola JM, Raynaud D, Korotkevich YS, Lorius C (1990) Ice-core record of atmospheric methane over the past 160,000 years. Nature (London) 345:127–131CrossRef

Ciais P, Tans P, White J, Trolier M, Francey R, Berry J, Randall D, Sellers P, Collatz J, Schimel DS (1995) Partitioning of ocean and land uptake of CO₂ as inferred by δ¹³C measurements from the NOAA/CMDL global air sampling network. J Geophys Res 100:5051–5070

Ciais P, Sabine C, Bala G, Bopp L, Brovkin V, Canadell J, Chhabra A, DeFries R, Galloway J, Heimann M, Jones C, Le Quéré C, Myneni RB, Piao S, Thornton P (2013) Carbon and other biogeochemical cycles. In: Stocker TF, Qin D, Plattner G-K, Tignor M, Allen SK, Boschung J, Nauels A, Xia Y, Bex V, Midgley PM (Hrsg) Climate change 2013: The physical science basis. Contribution of working group I to the fifth assessment report of the intergovernmental panel on climate change. Cambridge University Press, Cambridge

Cooper OR, Parrish DD, Ziemke J, Balashov NV, Cupeiro M, Galbally IE, Gilge S, Horowitz L, Jensen NR, Lamarque J-F, Naik V, Oltmans SJ, Schwab J, Shindell DT, Thompson AM, Thouret V, Wang Y, Zbinden RM (2014) Global distribution and trends of tropospheric ozone: an observation-based review. Elementa Sci Anthropocene 2:29. https://doi.org/10.12952/journal.elementa.000029

Crutzen PJ (1971) Ozone production rates in an oxygen-hydrogen-nitrogen oxid atmosphere. J Geophys Res 76:7311–7327CrossRef

Crutzen PJ, Arnold F (1986) Nitric acid cloud formation in the cold Antarctic stratosphere: A major cause for the springtime ozone hole. Nature (London) 324:651–655CrossRef

Crutzen PJ, Gidel LT (1983) A two-dimensional photochemical model of the atmosphere. 2: The tropospheric budgets of anthropogenic chlorocarbons CO, CH₄, CH₃Cl and the effect of various NOx sources on tropospheric ozone. J Geophys Res 88:6641–6661CrossRef

Crutzen PJ, Howard CJ (1978) The effect of the HO₂ + NO-reaction rate constant on one-dimensional model calculations of stratospheric ozone pertubations. Pure Appl Geophys 116:497–510CrossRef

Deshler T, Adriani A, Gobbi GP, Hofmann DJ, Di Donfrancesco G, Johnson BJ (1992) Volcanic aerosol and ozone depletion within the antarctic polar vortex during the austral spring of 1991. Geophys Res Lett 19:1819–1822CrossRef

Díaz S (1995) Elevated-CO₂ responsiveness,interactions at the community level, and plant functional types. J. Biogeogr 22: 289-295CrossRef

Dlugokencky EJ, Nisbet EG, Fisher R, Lowry D (2011) Global atmospheric methane: Budget, changes and dangers. Philos Trans R Soc London Ser A 369:2058–2072CrossRef

Dlugokencky EJ, Lang PM, Crotwell AM, Masarie KA (2012) Atmospheric methane dry air mole fractions from the NOAA ESRL Carbon Cycle Cooperative Global Air Sampling Network, 1983–2011. https://www.esrl.noaa.gov/psd/iasoa/dataset_record/?datasetid=5069. Zugegriffen: 20. Febr. 2017

Dodge MC (1977) Combined use of modeling techniques and smog chamber data to derive ozone-precursor relationships. International Conference on Photochemical Oxidant Pollution and its Control: Proceedings, Bd IIB, EPA/600/3-77-001b. U.S. Environmental Protection Agency, Research Triange Park, NC, S 881–889

Drdla K, Tabazadeh A, Turco RP, Jacobson MZ (1994) Analysis of the physical state of one arctic polar stratospheric cloud based on observations. Geophys Res Lett 21: 2475–2478CrossRef

Duncan BN, Logan JA, Bey I, Megretskaia IA, Yantosca RM, Novelli PC, JonesNB, Rinsland CP (2007) Global budget of CO, 1988–1997: Source estimates and validation with a global model. J Geophys Res 112:D22301

Fahey DW, Kawa SR, Woodbridge EL, Tin P, Wilson JC, Jonsson HH, Dye JE, Baumgardner D, Borrmann S, Toohey DW, Avallone LM, Proffitt MH, Margitan J, Loewenstein M, Podolske JR, Sawalitsch RJ, Wofsy SC, Ko MKW, Anderson DE, Schoeberl MR, Chan KR (1993) In situ measurements constraining the role of sulphate aerosols in mid-latitude ozone depletion. Nature 363:509–514CrossRef

Farman JC, Gardiner BG, Shanklin JD (1985) Large losses of total ozone in Antarctica reveal seasonal ClOx/NOx interaction. Nature (London) 315:207–210CrossRef

Frankenberg C, Meirink F, Bergamaschi P, Goede APH, Heimann M, Körner S, Platt U, van Weele M, Wagner T (2006) Satellite chartography of atmospheric methane from SCIAMACHY on board ENVISAT: Analysis of the years 2003 and 2004. J Geophys Res 111. https://doi.org/10.1029/2005JD006235

Frieler K, Rex M, Salawitch RJ, Canty T, Streibel M, Stimpfle RM, Pfeilsticker K, Dorf M, Weisenstein DK, Godin-Beekmann S (2005) Toward a better quantitative understanding of polar stratospheric ozone loss. Geophys Res Lett 33. https://doi.org/10.1029/2005GL025466CrossRef

Galbally IE, Roy CR (1980) Destruction of ozone at the earth’s surface. Quart J R Meteorol Soc 106:599–620CrossRef

GEA (2006) Energy resources and potentials. In: Global Energy Assessment – Toward a Sustainable Future. Cambridge University Press, Cambridge, S 425–512

Gleason JF, Bhartia BK, Herman JR, McPeters R, Newman P, Stolarski RS, Flynn L, Labow G, Larko D, Seftor C, Wellemeyer C, Komhyr WD, Miller AJ, Planet W (1993) Record low global ozone in 1992. Science 260:523–526CrossRef

Goudriaan J (1992) Biosphere structure, carbon sequestering potential and the atmospheric ¹⁴C carbon record. J Exp Bot 43: 1111–1119CrossRef

Graedel T E , Crutzen P J (1994) Chemie der Atmosphäre. Bedeutung für Klima und Umwelt. Spektrum Akademischer Verlag, Heidelberg

Hanson D, Mauersberger K (1988) Laboratory studies of the nitric acid trihydrate: Implications for the south polar stratosphere. Geophys Res Lett 15:855–858CrossRef

Hofmann DJ (1987) Perturbations of the global atmosphere associated with the El Chichon volcanic eruption of 1982. Rev Geophys 25:743–759CrossRef

Hofmann DJ, Solomon S (1989) Ozone destruction through heterogeneous chemistry following the eruption of El Chichon. J Geophys Res 94:5029–5041CrossRef

Hofmann DJ, Oltmans SJ, Harris JM, Solomon S, Deshler T, Johnson BJ (1992) Observation and possible causes of new ozone depletion in Antarctica in 1991. Nature 359:283–287CrossRef

Hofmann DJ, Oltmans SJ, Komhyr WD, Harris JM, Lathrop JA, Langford AO, Deshler T, Johnson BJ, Torres A, Matthews WA (1994) Ozone loss in the lower stratosphere over the United States in 1992–1993: Evidence for heterogeneous chemistry on the Pinatubo aerosol. Geophys Res Lett 21:65–68CrossRef

Hofmann DJ, Oltmans J, Harris JM, Johnson BJ, Lathrop JA (1997) Ten years of ozone sonde measurements at the south pole: Implications for recovery of springtime Antarctic ozone. J Geophys Res 102:8931–8943CrossRef

Hörmann C, Sihler H, Bobrowski N, Beirle S, Penning de Vries M, Platt U, Wagner T (2013) Systematic investigation of bromine monoxide in volcanic plumes from space by using the GOME-2 instrument. Atmos Chem Phys 13:4749–4781. https://doi.org/10.5194/acp-13-4749- 2013

Houghton RA, House JI, Pongratz J, van der Werf GR, DeFries RS, Hansen MC, Le Quéré C, Ramankutty N (2012) Carbon emissions from land use and land-cover change. Biogeosciences 9:5125–5142CrossRef

Idso KE, Idso SB (1994) Plant responses to atmospheric CO₂ enrichment in the face of environmental constraints: A review of the past 10 years’ research. Agr Forest Meteorol 69: 153–203CrossRef

Johnston HS (1971) Reduction of stratospheric ozone by nitrogen oxide catalysts from supersonic transport exhaust. Science 173:517–522CrossRef

Johnston HS (1975) Global ozone balance in the natural stratophere. Rev Geophys Space Phys 13:637–649CrossRef

Johnston HS, Podolske J (1978) Interpretations of stratospheric chemistry. Rev Geophys Space Phys 16:491–519

Jouzel J, Lorius C, Petit JR, Genthon C, Barkov NI, Kotlyakov VM, Petrov VM (1987) Vostok ice core: A continuous isotope temperature record over the last climatic cycle (160,000 years). Nature (London) 329:403–408CrossRef

Junge CE (1963) Air chemistry and radioactivity. Academic Press, New York

Keeling CD, Piper SC, Bacastow RB, Wahlen M, Whorf TP, Heimann M, Meijer HA (2005) Atmospheric CO₂ and ¹³CO₂ exchange with the terrestrial biosphere and oceans from 1978 to 2000: Observations and carbon cycle implications. In: Ehleringer JR, Cerling TE, Dearing MD (Hrsg) A History of Atmospheric CO₂ and Its Effects on Plants, Animals, and Ecosystems. Springer, New York, S 83–113

Keeling RF, Shertz S (1992) Seasonal and interannual variations in atmospheric oxygen and implications for the global carbon cycle. Nature 358:723–727CrossRef

van Keulen H, van Laar HH, Louwerse W, Goudriaan J (1980) Physiological aspects of increased CO₂ concentration. Experientia 36:787–792

Khatiwala S, Primeau F, Hall T (2009) Reconstruction of the history of anthropogenic CO₂ concentrations in the ocean. Nature 462:346–349CrossRef

Koike M, Jones YNB, Matthews WA, Johnston PV, McKenzie RL, Kinnison D, Rodriguez J (1994) Impact of Pinatubo aerosols on the partitioning between NO₂ and HNO₃. Geophys Res Lett 21:597–600

Körner C, Arnone III JA (1992) Responses to elevated carbon dioxide in artificial tropical ecosystems. Science 257: 1672–1675CrossRef

Lee C, Martin RV, van Donkelaar A, Lee H, Dickerson RR, Hains JC, Krotkov N, Richter A, Vinnikov K, Schwab JJ (2011) SO₂ emissions and lifetimes: Estimates from inverse modeling using in situ and global, space-based (SCIAMACHY and OMI) observations. J Geophys Res 116. https://doi.org/10.1029/2010JD014758

Le Quéré C., Andres RJ, Boden T, Conway T, Houghton RA, House JI, Marland G, Peters GP, van der Werf GR, Ahlström A, Andrew RM, Bopp L, Canadell JG, Ciais P, Doney SC., Enright C, Friedlingstein P, Huntingford C, Jain AK, Jourdain C, Kato E, Keeling RF., Klein Goldewijk K, Levis S, Levy P, Lomas M, Poulter B, Raupach MR, Schwinger J, Sitch S, Stocker BD, Viovy N, Zaehle S, and Zeng N (2013) The global carbon budget 1959–2011. Earth Syst Sci Data 5: 165–185

Levy H (1971) Normal atmosphere: Large radical and formaldehyde concentrations predicted, Science 173: 141–143CrossRef

Logan JA, Prather MJ, Wofsy SC, McElroy MB (1981) Tropospheric chemistry: A global perspective. J Geophys Res 86:7210–7254CrossRef

London J (1980) Radiative energy sources and sinks in the stratosphere and mesosphere. In: Nicolet M, Aikin AC (Hrsg) Proceedings of the nato advanced study institute on atmospheric ozone: Its variations and human influences. US Dept of Transportations, Washington DC, S 703–721

McElroy MB, Salawitch RJ, Wofsy SC, Logan JA (1986) Reductions of Antarctic ozone due to synergistic interactions of chlorine and bromine. Nature (London) 321:759–762CrossRef

Melillo JM, McGuire AD, Kicklighter DW, Moore B, Vorosmarty CJ, Schloss AL (1993) Global climate change and terrestrial net primary production, Nature, 363: 234–240CrossRef

Molina LT, Molina MJ (1987) Production of Cl₂O₂ by the self reaction of ClO radical. J Phys Chem 91:433–436

Molina MJ, Rowland FS (1974) Stratospheric sink for chlorofluoromethans: Chlorine atom catalyzed destruction of ozone. Nature (London) 249:810–812CrossRef

Möller D (2003) Luft: Chemie, Physik, Biologie, Reinhaltung, Recht. de Gruyter, Berlin

Nadelhoffer KJ, Emmett BA, Gundersen P, Kjnaas OJ, Koopmans CJ, Schleppi P, Tietema A, Wright RF (1999) Nitrogen deposition makes a minor contribution to carbon sequestration in temperate forests. Nature 398:145–148CrossRef

Neftel A, Oeschger H, Schwander J, Stauffer B, Zumbrunn R (1982) Ice core sample measurements give atmosphere CO₂ content during the past 40000 yrs. Nature (London) 295:220–223CrossRef

Neftel A, Moor E, Oeschger H, Stauffer B (1985) Evidence from polar ice cores for the increase in atmosphere CO₂ in the past two centuries. Nature (London) 315:45–47CrossRef

Oeschger H, Siegenthaler U, Schotterer U, Guglemann A (1975) A box diffusion model to study the carbon dioxide exchange in nature. Tellus 27:168–192CrossRef

Pawson S, Steinbrecht W, Charlton-Perez AJ, Fujiwara M, Karpechko AY, Petropavlovskikh I, Urban J, Weber M (2014) Update on global ozone: Past, present, and future. In: Scientific Assessment of Ozone Depletion: 2014, Global Ozone Research and Monitoring Project – Report No. 55. World Meteorological Organization, Genf, Schweiz

Peng TH (1984) Invasion of fossil fuel CO₂ into the ocean. In: Brutsaert W, Jirka GH (Hrsg) Gas transfer at water surfaces. Reidel, Dordrecht, S 515–523CrossRef

Peterson BJ, Melillo JM (1985) The potential storage of carbon caused by eutrophication of the biosphere. Tellus 37B: 117–127CrossRef

Prinn RG, Weiss RF, Fraser PJ et al (2000) A history of chemically and radiatively important gases in air deduced from ALE/GAGE/AGAGE. J Geophys Res Atmos 105:17751–17792CrossRef

Quay PD, Tilbrook B, Wong SC (1992) Oceanic uptake of fossil fuel CO₂: Carbon-13 evidence. Science 256:74–79CrossRef

Reineke W und Schlömann M (2007) Umweltmikrobiologie. Spektrum Akademischer Verlag, München

Rex M, Salawitch RJ, Deckelmann H et al (2006) Arctic winter 2005: Implications for stratospheric ozone loss and climate change. Geophys Res Lett 33. https://doi.org/10.1029/2006GL026731

Rigby M, Prinn RG, Fraser PJ et al (2008) Renewed growth of atmospheric methane. Geophys Res Lett 35. https://doi.org/10.1029/2008GL036037

Riley JP, Chester R (1971) Introduction to marine chemistry. Academic Press, London

Rodriguez JM, Ko MKW, Sze ND, Heisey CW (1994) Ozone response to enhanced heterogeneous processing after the eruption of Mt. Pinatubo. Geophys Res Lett 21:209–212

Schlesinger WH (1997) Biogeochemistry: An Analysis of Global Change. Academic Press, London

Schoeberl MR, Bhartia PK, Hilsenrath E (1993) Tropical ozone loss following the eruption of Mt. Pinatubo. Geophys Res Lett 20:29–32CrossRef

Seinfeld JH, Pandis SN (2006) Atmospheric Chemistry and Physics: From Air Pollution to Climae Change. 2. Aufl. John Wiley & Sons, New Jersey

Siegenthaler U (1983) Uptake of excess CO₂ by an outcrop-diffusion model of the ocean. J Geophys Res 88:3599–3608CrossRef

Siegenthaler U, Oeschger H (1978) Predicting future atmospheric carbon dioxide levels. Science 199:388–395CrossRef

Solomon S, Garcia RR, Rowland FS, Wuebbles DJ (1986) On the depletion of antarctic ozone. Nature (London) 321:755–758CrossRef

Stolarski RS, Bloomfield P, McPeters RD (1991) Total ozone trends deduced from Nimbus 7 TOMS data. Geophys Res Lett 18:1015–1018CrossRef

Takahashi T (1979) Carbon dioxide chemistry in ocean water. In: Elliott WP, Machta L (Hrsg) Carbon dioxide effects research and assessment program. U. S. Dept. of Energy, Washington, S 63–71

United Nations Environment Programme (UNEP) (2014) Sand, rarer than one thinks. Thematic focus: Ecosystem management, Environmental governance, Resource efficiency. http://www.unep.org/pdf/UNEP_GEAS_March_2014.pdf. Zugegriffen: 20. Febr. 2017

Volz A, Kley D (1988) Ozone measurements made in the 19th century: An evaluation of the Montsouris series. Nature (London) 332:240–242CrossRef

Wagener K (1979) The carbonate system of the ocean. In: Bolin B et al (Hrsg) The global carbon cycle. Wiley and Sons, New York, S 251–258

Wagner T, Beirle S, Deutschmann T, Grzegorski M, Platt U (2008) Dependence of cloud properties derived from spectrally resolved visible satellite observations on surface temperature. Atmos Chem Phys, 8: 2299–2312CrossRef

Wang Z, Sassen K (2000) Ozone destruction in continental stratus clouds: An aircraft case study. J Appl Meteorol 39:875–886CrossRef

Warneck P (1988) Chemistry of the natural atmosphere. Academic Press, San Diego

Wennberg PO, Cohen RC, Stimpfle RM, Koplow JP, Anderson JG, Sawalitsch RJ, Fahey DW, Woodbridge EL, Keim ER, Gao RS, Webster CR, May RD, Toohey DW, Avallone LM, Proffitt MH, Loewenstein M, Podolske JR, Chan KR, Wofsy SC (1994) Removal of stratospheric O₃ by radicals: In situ measurements of OH, HO₂, NO, NO₂, ClO and BrO. Science 266:398–404

Wofsy SC, McElroy MB, Yung YL (1975) The chemistry of atmospheric bromine. Geophys Res Lett 2:215–218CrossRef

Yung YL, Pinto JP, Watson RT, Sander SP (1980) Atmospheric bromine and ozone perturbations in the lower stratosphere. J Atmos Sci 37:339–353CrossRef

Title: Atmosphärische Spurengase
Authors: Walter Roedel
Thomas Wagner
Publisher: Springer Berlin Heidelberg
Book: Physik unserer Umwelt: Die Atmosphäre
Print ISBN: 978-3-662-54257-6

Electronic ISBN: 978-3-662-54258-3

Copyright Year: 2017
DOI: https://doi.org/10.1007/978-3-662-54258-3_8