Dry season assessment of carbon storage and emission from upland and riparian soils in the Ganga River basin

IF 3.1 2区 农林科学 Q2 SOIL SCIENCE
Sanchit Kumar, Anshumali
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Abstract

Soil organic carbon (C) and nitrogen (N) are profoundly affected by changes in land use and land cover (LULC), especially by farming in riparian zones. The five LULC classes were selected in contiguous order, i.e., undisturbed forest (CALref), conventional agriculture lands (CAL), reservoir riparian zones (RSRZ), river riparian zones (RRZ), and undisturbed riparian zones (RZref) in the Ganga River basin to study the C storage and emission trends at a landscape scale. The riparian soils showed higher moisture, temperature, and bulk density than the upland soils, strongly determining the spatial variations in the CO2 equivalent (CO2e), C:N ratio, and CO2 efflux. Riparian CO2e was more bulk density-dependent, while upland CO2e showed greater dependence on TOC. The C:N ratio showed a higher mean value in the reference soils (CALref and RZref) than in the other soils (P < 0.05). The total nitrogen (TN), total protein (TP), and NH4-N (ammonium‑nitrogen) showed the following trend: RSRZ > CAL > RRZ > RZref > CALref. The stepwise multiple regression models illustrated that soil moisture was the primary regulator of the C:N ratio and CO2 efflux in the upland soils while the temperature in the riparian soils. These intrinsic soil variables resulted in 1.15 to 2.26 times higher CO2 efflux from the cultivated soils (CAL, RSRZ, and RRZ) than from the reference soils. Hence, the present study revealed how agricultural practices tangibly increase the riparian system's carbon footprint while offering unsustainable livelihood options to farmers.

干季评估恒河流域高地和河岸土壤的碳储存和排放情况
土壤有机碳(C)和氮(N)受土地利用和土地覆盖(LULC)变化的影响很大,尤其是受河岸地带耕作的影响。我们在恒河流域按毗连顺序选择了五个 LULC 等级,即未受干扰的森林(CALref)、传统农田(CAL)、水库河岸带(RSRZ)、河流河岸带(RRZ)和未受干扰的河岸带(RZref),以研究景观尺度上的碳储存和排放趋势。河岸土壤的湿度、温度和容重均高于高地土壤,这在很大程度上决定了二氧化碳当量(CO2e)、碳氮比和二氧化碳流出量的空间变化。滨河土壤的二氧化碳当量更依赖于容重,而高地土壤的二氧化碳当量则更依赖于总有机碳。参考土壤(CALref 和 RZref)的碳氮比平均值高于其他土壤(P < 0.05)。总氮(TN)、总蛋白(TP)和 NH4-N(铵态氮)的变化趋势如下:RSRZ > CAL > RRZ > RZref > CALref。逐步多元回归模型表明,在高地土壤中,土壤水分是 C:N 比率和二氧化碳流出量的主要调节因素,而在河岸土壤中,温度则是主要调节因素。这些固有的土壤变量导致耕作土壤(CAL、RSRZ 和 RRZ)的二氧化碳流出量比参考土壤高出 1.15 至 2.26 倍。因此,本研究揭示了农业实践如何在为农民提供不可持续的生计选择的同时,切实增加了河岸系统的碳足迹。
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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来源期刊
Geoderma Regional
Geoderma Regional Agricultural and Biological Sciences-Soil Science
CiteScore
6.10
自引率
7.30%
发文量
122
审稿时长
76 days
期刊介绍: Global issues require studies and solutions on national and regional levels. Geoderma Regional focuses on studies that increase understanding and advance our scientific knowledge of soils in all regions of the world. The journal embraces every aspect of soil science and welcomes reviews of regional progress.
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