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Atmospheric 14CO2 Variations in the Equatorial Region

Published online by Cambridge University Press:  18 July 2016

Kazimierz Rozanski ,
Ingeborg Levin ,
Jürgen Stock ,
Raul E. Guevara Falcon  and
Fernando Rubio
Kazimierz Rozanski
Affiliation:
International Atomic Energy Agency, Wagramerstrasse 5, P.O. Box 100, A-1400, Vienna, Austria
Ingeborg Levin
Affiliation:
Institut für Umweltphysik, Universität Heidelberg, Im Neuenheimer Feld 366, D-69120 Heidelberg, Germany
Jürgen Stock
Affiliation:
Centro de Investigaciones de Astronomía, P.O. Box 264, Mérida 5101-A, Venezuela
Raul E. Guevara Falcon
Affiliation:
Radiocarbon Laboratory, Comisitón Ecuadoriana de Energia Atomica, San Javier 295 y Avenida Orellana, Quito, Ecuador
Fernando Rubio
Affiliation:
Radiocarbon Laboratory, Comisitón Ecuadoriana de Energia Atomica, San Javier 295 y Avenida Orellana, Quito, Ecuador
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Abstract

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We present here first results of 14CO2 monitoring at two sampling sites in the equatorial region of the South American continent (station Aychapicho, Ecuador and station Llano del Hato, Venezuela). We also include the data for two other stations representing undisturbed marine atmosphere at mid-latitudes of both hemispheres, far from large continental sources and sinks of CO2 (station Izaña, Tenerife, Spain and station Cape Grim, Tasmania). Between 1991 and 1993, 14CO2 levels in the tropical troposphere were generally higher by 2–5‰ when compared to mid-latitudes of both hemispheres. This apparent maximum of 14C in the tropics can be explained by two major factors: 1) emissions of 14C-free fossil fuel CO2, restricted mainly to mid-latitudes of the northern hemisphere; and 2) 14C depletion due to gas exchange with circumpolar Antarctic upwelling water, influencing mainly mid- and high southern latitudes. The δ14C record so far available for the Aychapicho station provides direct evidence for a regional reduction of atmospheric 14CO2 levels due to gas exchange with 14C-depleted equatorial surface ocean in the upwelling regions and dilution with the 14C-depleted CO2 released in these areas. Recurrent ENSO events, turning on and off the 14C-depleted CO2 source in the tropical Pacific, lead to relatively large temporal variations of the atmospheric 14C level in this region.

Type
IV. 14C as a Tracer of the Dynamic Carbon Cycle in the Current Environment
Information
Radiocarbon , Volume 37 , Issue 2 , 1995 , pp. 509 - 515
Copyright
Copyright © the Department of Geosciences, The University of Arizona 

References

Broecker, W. S. and Peng, T.-H. 1982 Tracers in the Sea. Palisades, New York, Lamont-Doherty Geological Observatory: 691 p.Google Scholar
Broecker, W. S., Peng, T.-H., Östlund, G. and Stuiver, M. 1985 The distribution of bomb radiocarbon in the ocean. Journal of Geophysical Research 90(C4): 69536970.CrossRefGoogle Scholar
Coplen, T. 1994 Reporting of stable hydrogen, carbon and oxygen isotopic abundances. Pure and Applied Chemistry 66: 273276.Google Scholar
Druffel, E. M. and Suess, H. E. 1983 On the radiocarbon record in banded corals: Exchange parameters and net transport of 14CO2 between atmosphere and surface ocean. Journal of Geophysical Research 88(C2): 12711280.Google Scholar
Enfield, D. B. 1989 E1 Niño, past and present. Reviews of Geophysics 27: 159187.Google Scholar
Francey, R. J., Allison, C. E., Enting, I. G., Beggs, H. S. and Tilbrook, B. 1993 The observed distribution of δ13C in the atmosphere. 4th International CO 2 Conference, Carqueiranne, France, September 13–17 (Extended abstracts) : 189192.Google Scholar
Freely, R. A., Wanninkhof, C. E., Cosca, C. E., Murphy, P. P. and Steckley, M. D. 1993 Air-sea exchange of CO2 in the central and eastern equatorial Pacific during the 1991–92. 4th International CO 2 Conference, Carqueiranne, France, September 13–17 (Extended abstracts) : 87.Google Scholar
Hesshaimer, V., Heimann, M. and Levin, I. 1994 Radiocarbon evidence for a smaller oceanic carbon dioxide sink than previously believed. Nature 370: 201203.Google Scholar
Jirikowic, J. L. and Kalin, R. M. 1993 A possible paleoclimatic ENSO indicator in the spatial variation of annual tree-ring 14C. Geophysical Research Letters 20(6): 439442.Google Scholar
Lefevre, N. and Dandonneau, Y. 1992 Air-sea CO2 fluxes in the equatorial Pacific in January–March 1991. Geophysical Research Letters 19(22): 22232226.Google Scholar
Levin, I., Bösinger, R., Bonani, G., Francey, R. J., Kromer, B., Münnich, K. O., Suter, M., Trivett, N. B. A. and Wölfli, W. 1992 Radiocarbon in atmospheric carbon dioxide and methane: Global distribution and trends. In Taylor, R. E., Long, A. and Kra, R. S., eds., Radiocarbon After Four Decades: An Interdisciplinary Perspective. New York, Springer-Verlag: 503518.Google Scholar
Levin, I., Münnich, K. O. and Weiss, W. 1980 The effect of anthropogenic CO2 and 14C sources on the distribution of 14C in the atmosphere. In Stuiver, M. and Kra, R. S., eds., Proceedings of the 10th International 14C Conference. Radiocarbon 22(2): 379391.Google Scholar
Stuiver, M. and Polach, H. A. 1977 Discussion: Reporting of 14C data. Radiocarbon 19(3): 355363.Google Scholar
WMO 1994 Climate System Monitoring (CSM) Monthly Bulletin , No. 1–1994. Geneva, World Meteorological Organization: 31 p.Google Scholar
Wong, C. S., Chan, Y.-H., Page, J. S., Smith, G. E. and Bellegay, R. D. 1993 Changes in equatorial CO2 flux and new production estimated from CO2 and nutrient levels in Pacific surface waters during the 1986/87 El Niño. Tellus 45B: 6479.Google Scholar