Longwei Dong, Jinzhi Ran, Jiali Luo, Lin Bai, Ying Sun, Muhammad Aqeel, Yahui Zhang, Xiaoting Wang, Qiajun Du, Junlan Xiong, Haiyang Gong, Qingqing Hou, Yan Deng, Rui Xia, Liang Wang, Fan Li, Chuancong Dong, Weigang Hu, Jie Peng, Ekaterina Filimonenko, Sulaiman Almwarai Alharbi, Jianxiao Zhu, Xiaogang Li, Chunjie Li, Jin-Sheng He, Karl J. Niklas, Yakov Kuzyakov, Jianming Deng
{"title":"草地和沙漠土壤中的无机碳库及其驱动因素","authors":"Longwei Dong, Jinzhi Ran, Jiali Luo, Lin Bai, Ying Sun, Muhammad Aqeel, Yahui Zhang, Xiaoting Wang, Qiajun Du, Junlan Xiong, Haiyang Gong, Qingqing Hou, Yan Deng, Rui Xia, Liang Wang, Fan Li, Chuancong Dong, Weigang Hu, Jie Peng, Ekaterina Filimonenko, Sulaiman Almwarai Alharbi, Jianxiao Zhu, Xiaogang Li, Chunjie Li, Jin-Sheng He, Karl J. Niklas, Yakov Kuzyakov, Jianming Deng","doi":"10.1111/gcb.17536","DOIUrl":null,"url":null,"abstract":"<div>\n \n <p>Inorganic carbon is an important component of soil carbon stocks, exerting a profound influence on climate change and ecosystem functioning. Drylands account for approximately 80% of the global soil inorganic carbon (SIC) pool within the top 200 cm. Despite its paramount importance, the components of SIC and their contributions to CO<sub>2</sub> fluxes have been largely overlooked, resulting in notable gaps in understanding its distribution, composition, and responses to environmental factors across ecosystems, especially in deserts and temperate grasslands. Utilizing a dataset of 6011 samples from 173 sites across 224 million hectares, the data revealed that deserts and grasslands in northwestern China contain 20 ± 2.5 and 5 ± 1.3 petagrams of SIC in the top 100 cm, representing 5.5 and 0.76 times the corresponding soil organic carbon stock, respectively. Pedogenic carbonates (PIC), formed by the dissolution and re-precipitation of carbonates, dominated in grasslands, accounting for 60% of SIC with an area-weighted density of 3.4 ± 0.4 kg C m<sup>−2</sup> at 0–100 cm depth, while lithogenic carbonates (LIC), inherited from soil parent materials, prevailed in deserts, constituting 55% of SIC with an area-weighted density of 7.1 ± 1.0 kg C m<sup>−2</sup>. Soil parent materials and elevation determined the SIC stocks by regulating the formation and loss of LIC in deserts, whereas natural acidification, mainly induced by rhizosphere processes including cation uptake and H<sup>+</sup> release as well as precipitation, reduced SIC (mainly by PIC) in grasslands. Overall, the massive SIC pool underscores its irreplaceable role in maintaining the total carbon pool in drylands. 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引用次数: 0
摘要
无机碳是土壤碳储量的重要组成部分,对气候变化和生态系统功能具有深远影响。旱地顶部 200 厘米范围内的土壤无机碳库约占全球土壤无机碳库的 80%。尽管土壤无机碳极为重要,但其成分及其对二氧化碳通量的贡献却在很大程度上被忽视了,导致人们对其分布、组成以及对不同生态系统(尤其是沙漠和温带草原)环境因素的反应的理解存在明显差距。利用来自 173 个地点、总面积达 2.24 亿公顷的 6011 个样本的数据集,研究发现中国西北部的沙漠和草地顶层 100 厘米的 SIC 含量分别为 20 ± 2.5 petagrams 和 5 ± 1.3 petagrams,分别是相应土壤有机碳储量的 5.5 倍和 0.76 倍。由碳酸盐溶解和再沉淀形成的沉积碳酸盐(Pedogenic carbonates, PIC)在草地中占主导地位,占 SIC 的 60%,0-100 厘米深度的面积加权密度为 3.4 ± 0.4 kg C m-2;而由土壤母质继承的沉积碳酸盐(Lithogenic carbonates, LIC)在沙漠中占主导地位,占 SIC 的 55%,面积加权密度为 7.1 ± 1.0 kg C m-2。土壤母质和海拔高度通过调节荒漠中LIC的形成和损失来决定SIC储量,而自然酸化(主要由根圈过程引起,包括阳离子吸收和H+释放以及降水)减少了草原中的SIC(主要是PIC)。总之,巨大的 SIC 库凸显了其在维持干旱地区总碳库中不可替代的作用。这项研究揭示了LIC和PIC,并强调了自然酸化对草地SIC损失的关键影响。
Inorganic Carbon Pools and Their Drivers in Grassland and Desert Soils
Inorganic carbon is an important component of soil carbon stocks, exerting a profound influence on climate change and ecosystem functioning. Drylands account for approximately 80% of the global soil inorganic carbon (SIC) pool within the top 200 cm. Despite its paramount importance, the components of SIC and their contributions to CO2 fluxes have been largely overlooked, resulting in notable gaps in understanding its distribution, composition, and responses to environmental factors across ecosystems, especially in deserts and temperate grasslands. Utilizing a dataset of 6011 samples from 173 sites across 224 million hectares, the data revealed that deserts and grasslands in northwestern China contain 20 ± 2.5 and 5 ± 1.3 petagrams of SIC in the top 100 cm, representing 5.5 and 0.76 times the corresponding soil organic carbon stock, respectively. Pedogenic carbonates (PIC), formed by the dissolution and re-precipitation of carbonates, dominated in grasslands, accounting for 60% of SIC with an area-weighted density of 3.4 ± 0.4 kg C m−2 at 0–100 cm depth, while lithogenic carbonates (LIC), inherited from soil parent materials, prevailed in deserts, constituting 55% of SIC with an area-weighted density of 7.1 ± 1.0 kg C m−2. Soil parent materials and elevation determined the SIC stocks by regulating the formation and loss of LIC in deserts, whereas natural acidification, mainly induced by rhizosphere processes including cation uptake and H+ release as well as precipitation, reduced SIC (mainly by PIC) in grasslands. Overall, the massive SIC pool underscores its irreplaceable role in maintaining the total carbon pool in drylands. This study sheds light on LIC and PIC and highlights the critical impact of natural acidification on SIC loss in grasslands.
期刊介绍:
Global Change Biology is an environmental change journal committed to shaping the future and addressing the world's most pressing challenges, including sustainability, climate change, environmental protection, food and water safety, and global health.
Dedicated to fostering a profound understanding of the impacts of global change on biological systems and offering innovative solutions, the journal publishes a diverse range of content, including primary research articles, technical advances, research reviews, reports, opinions, perspectives, commentaries, and letters. Starting with the 2024 volume, Global Change Biology will transition to an online-only format, enhancing accessibility and contributing to the evolution of scholarly communication.
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