Soil erosion and atmospheric CO2 during the last glacial maximum: the rôle of riverine organic matter fluxes

IF 2.3 4区地球科学 Q3 METEOROLOGY & ATMOSPHERIC SCIENCES

Tellus Series B-Chemical and Physical Meteorology Pub Date : 1999-04-01 DOI:10.3402/TELLUSB.V51I2.16267

W. Ludwig, J. Probst

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引用次数: 6

Abstract

Atmospheric CO 2 is consumed both by organic matter formation and chemical rock weathering, and subsequently discharged as dissolved organic carbon, particulate organic carbon, and dissolved inorganic carbon to the oceans by rivers. In the long term, varying the ratio of the amount of atmospheric CO 2 consumed by continental erosion and the amount of CO 2 released during carbonate precipitation and organic matter respiration in the oceans can change the CO 2 content in the atmosphere. The purpose of this paper is to determine whether riverine organic carbon fluxes during the last glacial maximum (LGM) may have been different from today in order to assess the potential impact on atmospheric CO 2 . Previous studies mainly focused on the role of the river fluxes of inorganic carbon in this respect, but none of them examined possible variations in the fluxes of organic carbon, although the erosion of organic carbon actually represents the bulk of the atmospheric CO 2 consumption by continental erosion. We therefore applied a global carbon erosion model to a LGM scenario in order to determine the riverine fluxes of organic matter during that time. The climatic conditions during the LGM were reconstructed using a computer simulation with a general circulation model. It is found that during the LGM the riverine organic carbon input into the oceans was at least ∼10% lower than today. Most of the reduction of the total organic matter fluxes is due to the reduction of the fluxes of dissolved organic carbon. The fluxes of particulate organic carbon remained almost unchanged. The oceanic response to the lower carbon input was estimated on the basis of a present-day steady state budget for organic river carbon in the oceans, and implies that the reduction of the river fluxes were more than counterbalanced by lower burial rates due to the smaller shelf area during the LGM. This suggests that both the lower river carbon input and the relatively greater share of this carbon being subjected to oceanic respiration, acted as a negative feedback to the low atmospheric CO 2 content during the LGM. DOI: 10.1034/j.1600-0889.1999.t01-1-00003.x

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末次盛冰期土壤侵蚀与大气CO2:河流有机质通量rôle

大气中的二氧化碳通过有机质形成和化学岩石风化作用被消耗，随后以溶解有机碳、颗粒有机碳和溶解无机碳的形式通过河流排入海洋。从长远来看，改变大陆侵蚀消耗的大气CO 2量与海洋中碳酸盐降水和有机物呼吸释放的CO 2量的比例可以改变大气中的CO 2含量。本文的目的是确定末次盛冰期(LGM)的河流有机碳通量是否可能与今天不同，以便评估对大气CO 2的潜在影响。以前的研究主要集中在无机碳的河流通量在这方面的作用，但它们都没有研究有机碳通量的可能变化，尽管有机碳的侵蚀实际上代表了大陆侵蚀所消耗的大部分大气CO 2。因此，我们将全球碳侵蚀模型应用于LGM情景，以确定该时期的河流有机质通量。利用一般环流模式的计算机模拟，重建了LGM期间的气候条件。研究发现，在LGM期间，河流输入海洋的有机碳至少比今天低10%。总有机质通量的减少大部分是由于溶解有机碳通量的减少。颗粒有机碳的通量几乎保持不变。海洋对低碳输入的响应是根据目前海洋中有机河流碳的稳定状态预算估算的，这意味着河流通量的减少被低埋率所抵消，而低埋率是由于LGM期间陆架面积较小造成的。这表明，在LGM期间，较低的河流碳输入和相对较大的海洋呼吸碳份额对低大气CO 2含量起了负反馈作用。DOI: 10.1034 / j.1600 0889.1999.t01 - 1 - 00003. x

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来源期刊

Tellus Series B-Chemical and Physical Meteorology 地学-气象与大气科学

自引率

0.00%

发文量

期刊介绍： Tellus B: Chemical and Physical Meteorology along with its sister journal Tellus A: Dynamic Meteorology and Oceanography, are the international, peer-reviewed journals of the International Meteorological Institute in Stockholm, an independent non-for-profit body integrated into the Department of Meteorology at the Faculty of Sciences of Stockholm University, Sweden. Aiming to promote the exchange of knowledge about meteorology from across a range of scientific sub-disciplines, the two journals serve an international community of researchers, policy makers, managers, media and the general public.