Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-27T21:37:09.175Z Has data issue: false hasContentIssue false

Uptake of Anthropogenic Co2 by Lateral Transport Models of the Ocean Based on the Distribution of Bomb-Produced 14C

Published online by Cambridge University Press:  18 July 2016

Tsung-Hung Peng*
Affiliation:
Environmental Sciences Division, Oak Ridge National Laboratory Oak Ridge, Tennessee 37831
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

The pattern of global water column inventories of bomb-produced 14C suggests that a sizeable portion of bomb 14C that entered the Antarctic, northern Pacific, and tropical oceans has been transported to adjacent temperate regions. Models of lateral transport of surface water in the Atlantic, Indian, and Pacific Oceans are based on this distribution pattern. Upwelling of bomb-14C-free water from below takes place in the Antarctic, northern Pacific, and tropical regions; downwelling of surface water occurs in the temperate oceans and northern Atlantic. Uptake of excess CO2 by these models is calculated using the observed Mauna Loa pCO2 record as an input function. Results indicate that 35% of fossil fuel CO2 is taken up by these model oceans during the period 1958–1980. Considering the observed airborne fraction of 0.55, it appears that ca 10% of the global fossil fuel CO2 is still missing.

Type
III. The Carbon Cycle
Copyright
Copyright © The American Journal of Science 

References

Bacastow, R B and Keeling, C D, 1981, Atmospheric carbon dioxide concentration and the observed airborne fraction, in Bolin, B, ed, Carbon cycle modeling: New York, John Wiley & Sons, p 103112.Google Scholar
Bien, G C, Rakestraw, N W and Suess, H E, 1960, Radiocarbon concentration in the Pacific Ocean water: Tellus, v 12, p 436443.Google Scholar
Bien, G C, Rakestraw, N W and Suess, H E, 1965, Radiocarbon in the Pacific and Indian Oceans and its relation to deep water movements: Limnol & Oceanog, v 10, p R25R36.Google Scholar
Broecker, W S, Gerard, R, Ewing, M and Heezen, B C, 1960, Natural radiocarbon in the Atlantic Ocean: Jour Geophys Research, v 65, p 29032931.Google Scholar
Broecker, W S, Peng, T-H and Engh, R, 1980, Modeling the carbon system, in Stuiver, M and Kra, R S, eds, Internatl 14C conf, 10th, Proc: Radiocarbon, v 22, no. 3, p 565598.Google Scholar
Broecker, W S, Peng, T-H, Ostlund, G and Stuiver, M, 1985, The distribution of bomb radiocarbon in the ocean: Jour Geophys Research, v 90, p 69536970.Google Scholar
Druffel, E M and Linick, T W, 1978, Radiocarbon in annual coral rings of Florida: Geophys Research Letters, v 5, p 913916.Google Scholar
Houghton, R A, Hobbie, J E, Melillo, J M, Moore, B, Peterson, B J, Shaver, G R and Woodwell, G M, 1983, Changes in the carbon content of terrestrial biota and soils between 1860 and 1980: A net release of CO2 to the atmosphere: Ecolog Mono, v 53, no. 3, p 235262.Google Scholar
Keeling, C D, 1973, Industrial production of carbon dioxide from fossil fuel and limestone: Tellus, v 25, p 173198.Google Scholar
Li, Y-H, Peng, T-H, Broecker, W S and Ostlund, H G, 1984, The average vertical mixing coefficient for the oceanic thermocline: Tellus, v 36B, p 212217.Google Scholar
Neftel, A, Moor, E, Oeschger, H and Stauffer, B, 1985, Evidence from polar ice cores for the increase in atmospheric CO2 in the past two centuries: Nature, v 315, p 4547.CrossRefGoogle Scholar
Nozaki, Y, Rye, D M, Turekian, K K and Dodge, R E, 1978, A 200 year record of carbon-13 and carbon-14 variations in a Bermuda coral: Geophys Research Letters, v 5, p 825828.Google Scholar
Nydal, R and Lovseth, K, 1983, Tracing bomb 14C in the atmosphere 1962–1980: Jour Geophys Research, v 88, p 36213642.Google Scholar
Oeschger, H, Siegenthaler, U, Schotterer, U and Gugelmann, A, 1975, A box diffusion model to study the carbon dioxide exchange in nature: Tellus, v 27, p 168192.CrossRefGoogle Scholar
Ostlund, H G and Stuiver, M, 1980, GEOSECS Pacific radiocarbon: Radiocarbon, v 22, p 2553.Google Scholar
Peng, T-H, Broecker, W S, Freyer, H D and Trumbore, S, 1983, A deconvolution of the tree-ring based 13C record: Jour Geophys Research, v 88, p 36093620.CrossRefGoogle Scholar
Peng, T-H, 1984, Invasion of fossil fuel CO2 into the ocean, in Brutsaert, W and Jirka, G H, eds, Gas transfer at water surfaces: Hingham, Massachusetts, D Reidel Pub, Kluwer Acad Pub, p 515523.CrossRefGoogle Scholar
Rafter, T A and O'Brien, B J, 1970, Exchange rates between the atmosphere and the ocean as shown by recent C-14 measurements in the South Pacific, in Olsson, I U, ed, Nobel symposium, 12th, Proc: John Wiley & Sons, p 355377.Google Scholar
Raynaud, D and Barnola, J M, 1985, An Antarctic ice core reveals atmospheric CO2 variations over the past few centuries: Nature, v 315, p 309311.Google Scholar
Rotty, R M, 1981, Data for global CO2 production from fossil fuels and cement, in Bolin, B, ed, Carbon cycle modeling: New York, John Wiley & Sons, p 121126.Google Scholar
Rotty, R M, 1983, Distribution of and changes in industrial carbon dioxide production: Jour Geophys Research, v 88, p 13011308.Google Scholar
Stuiver, M, 1980, 14C distribution in the Atlantic Ocean: Jour Geophys Research, v 85, p 27112718.CrossRefGoogle Scholar
Stuiver, M and Ostlund, H G, 1980, GEOSECS Atlantic radiocarbon: Radiocarbon, v 22, p 124.Google Scholar
Stuiver, M and Ostlund, H G, 1983, GEOSECS Indian and Mediterranean radiocarbon: Radiocarbon, v 25, p 129.Google Scholar
Stuiver, M, Ostlund, H G and McConnaughey, T A, 1981, GEOSECS Atlantic and Pacific 14C distribution, in Bolin, B, ed, Carbon cycle modeling: New York, John Wiley & Sons, p201209.Google Scholar
Takahashi, T, Broecker, W S and Bainbridge, A E, 1981, Supplement to the alkalinity and total carbon dioxide concentration in the world oceans, in Bolin, B, ed, Carbon cycle modeling: New York, John Wiley & Sons, p 159200.Google Scholar