| DOI: | 10.5194/cp-8-545-2012
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| Scopus记录号: | 2-s2.0-84858762454
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| 论文题名: | Quantifying the ocean's role in glacial CO2 reductions |
| 作者: | Chikamoto M.O.; Abe-Ouchi A.; Oka A.; Ohgaito R.; Timmermann A.
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| 刊名: | Climate of the Past
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| ISSN: | 18149324
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| 出版年: | 2012
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| 卷: | 8, 期:2 | | 起始页码: | 545
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| 结束页码: | 563
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| 语种: | 英语
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| Scopus关键词: | Antarctic Bottom Water
; carbon cycle
; carbon dioxide
; carbon isotope
; dissolved inorganic carbon
; general circulation model
; ice cover
; isotopic ratio
; Last Glacial Maximum
; North Atlantic Deep Water
; Northern Hemisphere
; paleoceanography
; paleoclimate
; sea ice
; sea surface temperature
; solubility
; Atlantic Ocean
; Atlantic Ocean (North)
; Atlantic Ocean (South)
; Southern Ocean
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| 英文摘要: | A series of Last Glacial Maximum (LGM) marine carbon cycle sensitivity experiments is conducted to test the effect of different physical processes, as simulated by two atmosphere-ocean general circulation model (AOGCM) experiments, on atmospheric pCO 2. One AOGCM solution exhibits an increase in North Atlantic Deep Water (NADW) formation under glacial conditions, whereas the other mimics an increase in Antarctic Bottom Water (AABW) associated with a weaker NADW. None of these sensitivity experiments reproduces the observed magnitude of glacial/interglacial pCO 2 changes. However, to explain the reconstructed vertical gradient of dissolved inorganic carbon (DIC) of 40 mmol mĝ̂'3 a marked enhancement in AABW formation is required. Furthermore, for the enhanced AABW sensitivity experiment the simulated stable carbon isotope ratio (δ13C) decreases by 0.4‰ at intermediate depths in the South Atlantic in accordance with sedimentary evidence. The shift of deep and bottom water formation sites from the North Atlantic to the Southern Ocean increases the total preformed nutrient inventory, so that the lowered efficiency of Southern Ocean nutrient utilization in turn increases atmospheric pCO 2. This change eventually offsets the effect of an increased abyssal carbon pool due to stronger AABW formation. The effects of interhemispheric glacial sea-ice changes on atmospheric pCO 2 oppose each other. Whereas, extended sea-ice coverage in the Southern Hemisphere reduces the air-sea gas exchange of CO2 in agreement with previous theoretical considerations, glacial advances of sea-ice in the Northern Hemisphere lead to a weakening of the oceanic carbon uptake through the physical pump. Due to enhanced gas solubility associated with lower sea surface temperature, both glacial experiments generate a reduction of atmospheric pCO 2 by about 20-23 ppmv. The sensitivity experiments presented here demonstrate the presence of compensating effects of different physical processes in the ocean on glacial CO2 and the difficulty of finding a simple explanation of the glacial CO2 problem by invoking ocean dynamical changes. © Author(s) 2012. |
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| 资源类型: | 期刊论文
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| 标识符: | http://119.78.100.158/handle/2HF3EXSE/49613
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| Appears in Collections: | 气候变化与战略
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| Recommended Citation: | |
Chikamoto M.O.,Abe-Ouchi A.,Oka A.,et al. Quantifying the ocean's role in glacial CO2 reductions[J]. Climate of the Past,2012-01-01,8(2)
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