Spatial Distribution of Surface Soil Organic Carbon of Chadan Wetland in the Source Region of Yangtze River

doi:10.11988/ckyyb.20231285

Journal of Changjiang River Scientific Research Institute ›› 2025, Vol. 42 ›› Issue (3): 193-201.DOI: 10.11988/ckyyb.20231285

• Scientific Expedition and Research in the Headwaters of the Yangtze River • Previous Articles Next Articles

Spatial Distribution of Surface Soil Organic Carbon of Chadan Wetland in the Source Region of Yangtze River

ZHANG Shuang-yin¹^,²(), XU Ping³, WANG Mi⁴, ZHAO Bao-cheng¹, FU Chong-qing¹, ZHENG Hang⁵, XU Jian¹, ZHAO Deng-zhong⁶, CHENG Xue-jun¹, ZHENG Xue-dong¹()

¹ Spatial Information Technology Application Department,Changjiang River Scientific Research Institute,Wuhan 430010, China
² Wuhan Research Center on Intelligent River Basin Engineering Technology,Wuhan 430010,China
³ Field Scientific Observation Center, Changjiang River Scientific Research Institute, Wuhan 430010,China
⁴ State Key Laboratory of Information Engineering in Surveying,Mapping and Remote Sensing,Wuhan University, Wuhan 430079, China
⁵ Changjiang Survey, Planning and Design Research Co., Ltd.,Wuhan 430010,China
⁶ International Cooperation Department, Changjiang River Scientific Research Institute, Wuhan 430010, China

Received:2023-11-22 Revised:2024-01-27 Published:2025-03-01 Online:2025-03-01
Contact: ZHENG Xue-dong

Abstract

Abstract:

Alpine wetlands serve as substantial carbon sinks and play a crucial role in providing habitats for wildlife and maintaining ecological security on the plateau. Current research predominantly focuses on areas below 4 000 meters in altitude, while studies on the surface soil organic carbon (SOC) of alpine wetlands above 4 000 meters require further enhancement. In this study, we analyzed the spatial distribution of surface SOC contents and their proportions in the total carbon of alpine wetlands. We utilized samples from 20 monitoring sites (with 3 replicates at each site) in the Chadan wetland, the highest-elevation wetland (average elevation over 4500 m) in the source region of the Yangtze River. Additionally, we explored the spatial differences among different tributaries. Results indicated that the surface SOC content in the Chadan wetland ranged from 0.54% to 18.47%, with an average of 4.78%. Moreover, its proportion in the total carbon exceeded 80%. The spatial correlations of total carbon and total organic carbon in tributaries on the north and south banks are opposite. This study advanced our understanding of the spatial distribution of surface SOC in alpine wetlands and provided preliminary exploration and validation data for more accurate estimations of carbon sink storage in high-altitude alpine wetlands.

Key words: headwaters of the Yangtze River, alpine wetland, Chadan wetland, total organic carbon, Carbon occurrence

CLC Number:

ZHANG Shuang-yin, XU Ping, WANG Mi, ZHAO Bao-cheng, FU Chong-qing, ZHENG Hang, XU Jian, ZHAO Deng-zhong, CHENG Xue-jun, ZHENG Xue-dong. Spatial Distribution of Surface Soil Organic Carbon of Chadan Wetland in the Source Region of Yangtze River[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(3): 193-201.

样本	统计值	总碳含量/ %	总有机碳含量/ %	样本	统计值	总碳含量/ %	总有机碳含量/ %
总样本表层土	最小值	0.89	0.54	南岸支流表层土	最小值	0.89	0.54
	中值	3.57	3.31		中值	3.00	2.64
	最大值	18.94	18.47		最大值	5.73	5.39
	均值	4.78	4.47		均值	3.22	2.89
	标准差	4.40	4.35		标准差	1.74	1.73
	变异系数	0.92	0.97		变异系数	0.54	0.60
干流表层土	最小值	1.51	1.30	北岸支流表层土	最小值	1.50	1.24
	中值	3.04	2.80		中值	5.58	5.23
	最大值	6.54	6.25		最大值	18.94	18.47
	均值	3.53	3.28		均值	8.07	7.72
	标准差	2.10	2.06		标准差	6.80	6.70
	变异系数	0.59	0.63		变异系数	0.84	0.87

样本	统计值	总碳含量/ %	总有机碳含量/ %	样本	统计值	总碳含量/ %	总有机碳含量/ %
总样本表层土	最小值	0.89	0.54	南岸支流表层土	最小值	0.89	0.54
	中值	3.57	3.31		中值	3.00	2.64
	最大值	18.94	18.47		最大值	5.73	5.39
	均值	4.78	4.47		均值	3.22	2.89
	标准差	4.40	4.35		标准差	1.74	1.73
	变异系数	0.92	0.97		变异系数	0.54	0.60
干流表层土	最小值	1.51	1.30	北岸支流表层土	最小值	1.50	1.24
	中值	3.04	2.80		中值	5.58	5.23
	最大值	6.54	6.25		最大值	18.94	18.47
	均值	3.53	3.28		均值	8.07	7.72
	标准差	2.10	2.06		标准差	6.80	6.70
	变异系数	0.59	0.63		变异系数	0.84	0.87

区域	单变量Moran’s I			双变量Moran’s I
区域	TC	TOC	TOC/ TC	TC-TOC	TC-TOC/ TC	TOC-TOC/ TC
所有区域	0.09	0.09	0.16	0.09	0.06	0.06
干流	0.07	0.05	0.12	0.06	0.13	0.12
北岸支流	-0.21	-0.21	-0.34	-0.21	-0.32	-0.32
南岸支流	0.30	0.29	0.09	0.30	0.28	0.27

区域	单变量Moran’s I			双变量Moran’s I
区域	TC	TOC	TOC/ TC	TC-TOC	TC-TOC/ TC	TOC-TOC/ TC
所有区域	0.09	0.09	0.16	0.09	0.06	0.06
干流	0.07	0.05	0.12	0.06	0.13	0.12
北岸支流	-0.21	-0.21	-0.34	-0.21	-0.32	-0.32
南岸支流	0.30	0.29	0.09	0.30	0.28	0.27

研究区	海拔/ m	土壤有机碳含量/%	影响因素	文献
青海湖湿地	约3 200	2.82	植被类型	曹生奎等^[7], 2013
纳帕海国际重要湿地	3 260	<36	围栏放牧、土壤含水率等	刘爽等^[20], 2023
黄河源区玛沁县湿地	3 731	<16	草地退化、土壤深度等	林春英等^[9], 2021
若尔盖湿地	3 400~ 3 900	<12	水分梯度、 pH值等	高俊琴等^[27], 2008
若尔盖湿地	3 400~ 3 900	8.94 (沼泽土) 45.20 (泥炭土)	有机质来源、沉积环境	高俊琴等^[26], 2006
鄱阳湖湿地	约10	<2	土壤pH值、含水量等	袁继红等^[24], 2023
洞庭湖湿地	约40	<4	土壤深度、植物类型等	梁春玲^[28], 2020

Spatial Distribution of Surface Soil Organic Carbon of Chadan Wetland in the Source Region of Yangtze River

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