湄公河流域化学风化的季节和空间变化:从上游到下游

IF 1.7 4区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS Aquatic Geochemistry Pub Date : 2020-04-23 DOI:10.1007/s10498-020-09374-y
Hiroto Kajita, Yuki Ota, Toshihiro Yoshimura, Daisuke Araoka, Takuya Manaka, Ouyang Ziyu, Shinya Iwasaki, Takuya Yanase, Akihiko Inamura, Etsuo Uchida, Hongbo Zheng, Qing Yang, Ke Wang, Atsushi Suzuki, Hodaka Kawahata
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引用次数: 6

摘要

喜马拉雅河流域的化学风化是世界上最严重的,并且受到了与过去气候变化相关的广泛关注。许多化学风化的早期估计是基于少量的水性质数据,忽略了这些空间和季节变化。因此,本研究分析了湄公河流域化学风化的空间和季节变化,从下游到上游,从旱季到雨季,流域的地质、气候和水文循环变化明显。我们利用整个盆地和两个季节河水的众多化学成分分别估算了溶解元素的来源和潜在的二氧化碳消耗率。雨季的CO2消耗率是旱季的三到五倍,这可能是由于高温和降水造成的。尽管上游和中部盆地温度较低且较为干燥,但CO2消耗速率约为下游的两倍;这可归因于陡峭山区的活跃物理剥蚀,这增加了水岩相互作用的表面积。结合各季节和流域得到的CO2总消耗量为48 × 70 × 109?Mol /a和148 × 159 × 109?Mol /a,分别为硅酸盐和碳酸盐风化,几乎是以前估计值的一半。我们的研究结果表明,季节和空间分离的评价对于生成喜马拉雅大河流的化学风化估算是重要的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Seasonal and Spatial Variations of Chemical Weathering in the Mekong Basin: From the Headwaters to the Lower Reaches

Chemical weathering in the Himalayan river basins is among the highest in the world and has received vast research attention related to past climate change. Many early estimates of chemical weathering are based on a small number of water property data that ignore those spatial and seasonal variations. Therefore, this study analyzed spatial and seasonal variations in chemical weathering in the Mekong Basin, where the geology, climate, and hydrologic cycle of the basin vary significantly from the lower to upper reaches and from dry to rainy seasons. We separately estimated the origins of dissolved elements and potential CO2 consumption rates using the numerous chemical compositions of river water throughout the entire basin and in both seasons. The CO2 consumption rate in the rainy season is three to five times that in the dry season that may be due to the high temperature and precipitation. Despite the low temperatures and dryness of the upper and middle basins, the CO2 consumption rate is approximately twice that in the lower reaches; this can be attributed to active physical denudation in steep mountainous areas which increases the surface area for water–rock interactions. The total CO2 consumption obtained by combining each season and basin was 48?70?×?109?mol/a and 148?159?×?109?mol/a for silicate and carbonate weathering, respectively, which are almost half the values of previous estimates. Our results suggest that seasonally and spatially separated evaluations are important for generating estimates of chemical weathering in large Himalayan rivers.

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来源期刊
Aquatic Geochemistry
Aquatic Geochemistry 地学-地球化学与地球物理
CiteScore
4.30
自引率
0.00%
发文量
6
审稿时长
1 months
期刊介绍: We publish original studies relating to the geochemistry of natural waters and their interactions with rocks and minerals under near Earth-surface conditions. Coverage includes theoretical, experimental, and modeling papers dealing with this subject area, as well as papers presenting observations of natural systems that stress major processes. The journal also presents `letter''-type papers for rapid publication and a limited number of review-type papers on topics of particularly broad interest or current major controversy.
期刊最新文献
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