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| Spatio-temporal variations in the soil organic carbon and total nitrogen contents in the Muling River-Xingkai Lake Plain |
ZHANG Yi-He1,2,3( ), YANG Ze1,2,3, DAI Hui-Min1,2,3, LIU Guo-Dong1,2,3, HAN Xiao-Meng1,2,3, LI Qiu-Yan1,2,3() |
1. Shenyang Center of China Geological Survey, Shenyang 110034, China
2. Key Laboratory of Black Soil Evolution and Ecological Effect, Ministry of Natural Resources, Shenyang 110034, China
3. Key Laboratory of Black Soil Evolution and Ecological Effect, Liaoning Province, Shenyang 110034, China |
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Abstract The soil organic carbon (SOC) and total nitrogen (TN) contents serve as the basis for sustainable agriculture and the key to soil fertility and play an important role in maintaining the soil nutrient content. Based on the soil nutrient element data obtained from the 1:250,000 land quality geochemical survey and the second national soil census, this study investigated the spatio-temporal variations in the SOC and TN contents in the surface soil of the Muling River-Xingkai Lake Plain from 1979 to 2019 using the geostatistical method and the geographic information system (GIS) technique. The results show that the SOC and TN contents in the surface soil of the study area are mainly at grade Ⅲ or above. They are rich or highly rich overall but are deficient locally. During 40 years of evolution, the SOC and TN contents decreased by 25.65% and 29.87%, respectively, and the C/N ratio increased by 6.00%. Compared with those in 1979, the SOC and TN contents in the surface soil decreased in different soil types except for paddy soil. The transition from the natural ecosystem into farmland also decreased the SOC and TN contents. These results indicate that factors such as changes in soil types and land uses have significant effects on the degree of the spatial variations in soil nutrients in the study area.
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Received: 27 January 2022
Published: 03 January 2023
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Corresponding Authors:
LI Qiu-Yan
E-mail: 343847617@qq.com;2284435292@qq.com
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| 序号 | 元素 | 检出限 | 分析方法 | | 实测 | 要求 | 单位 | | 1 | N | 17 | 20 | 10-3 | 容量法 | | 2 | Corg | 0.02 | 0.1 | 10-3 | 容量法 |
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Analytical methods and detection limits of nitrogen and organic matter in soil
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| 指标 | 样品数 | 最小值 | 最大值 | 平均值 | 标准差 | 变异系数/% | 偏度系数 | 峰度系数 | | 2019年 | SOC | 3920 | 3.47 | 52.41 | 26.47 | 8.53 | 32.24 | 0.53 | 0.07 | | TN | 3920 | 0.22 | 4.30 | 2.23 | 0.68 | 30.38 | 0.47 | -0.03 | | C/N | 3920 | 4.63 | 23.75 | 11.85 | 1.20 | 10.14 | 1.59 | 11.85 | | 1979年 | SOC | 3920 | 9.92 | 80.05 | 35.60 | 18.43 | 51.78 | 0.88 | 0.08 | | TN | 3920 | 1.00 | 7.30 | 3.18 | 1.64 | 51.48 | 1.08 | 0.08 | | C/N | 3920 | 7.65 | 16.38 | 11.18 | 1.30 | 11.66 | -0.29 | 0.08 |
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Statistical characteristics of soil SOC, TN and C/N in the study area
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| 指标 | 拟合模型 | 块金值(C0) | 基台值(C0+C) | [C0/(C0+C)]/% | 变程/km | 拟合度R2 | | SOC | 指数模型 | 46.3 | 143.6 | 32.2 | 697.8 | 0.955 | | TN | 球状模型 | 0.26 | 0.799 | 32.9 | 311 | 0.971 | | C/N | 指数模型 | 0.72 | 1.433 | 50 | 61.8 | 0.894 |
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Soil SOC, TN, C/N semi-variance function model parameters
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Spatial distribution of soil SOC, TN and C/N
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| 指标 | 一等/
丰富 | 二等/
较丰富 | 三等/
中等 | 四等/
较缺乏 | 五等/
缺乏 | | TN | 面积/km2 | 10120 | 4308 | 1944 | 112 | 124 | | 比例/% | 60.93 | 25.94 | 11.71 | 0.67 | 0.75 | | SOC | 面积/km2 | 10364 | 4120 | 1812.00 | 260 | 52 | | 比例/% | 62.40 | 24.81 | 10.91 | 1.57 | 0.31 |
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Distribution area and proportion of soil SOC and TN grade
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土壤
类型 | 2019年 | 1979年 | | SOC | TN | C/N | SOC | TN | C/N | | 沼泽土 | 30.14 | 2.57 | 11.74 | 54.03 | 4.74 | 11.59 | | 草甸土 | 25.93 | 2.19 | 11.82 | 28.58 | 2.53 | 11.71 | | 白浆土 | 25.90 | 2.21 | 11.72 | 27.04 | 2.50 | 10.59 | | 黑土 | 25.44 | 2.12 | 11.96 | 30.66 | 2.73 | 11.32 | | 暗棕壤 | 24.98 | 2.05 | 12.15 | 41.04 | 3.61 | 11.40 | | 水稻土 | 24.72 | 2.04 | 11.99 | 22.13 | 2.03 | 10.69 |
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Content characteristics of SOC, TN and C/N in different soil types
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土地利
用变化 | 样本数 | SOC变化 | TN变化 | C/N变化 | | 10-3 | 10-3 | | 湿地→旱地 | 232 | -13.12 | -1.25 | 0.19 | | 湿地→水田 | 629 | -11.81 | -1.20 | 0.51 | | 林地→旱地 | 327 | -11.39 | -1.19 | 1.05 | | 旱田→水田 | 284 | -8.47 | -0.80 | 0.22 | | 旱地-旱地 | 716 | -4.84 | -0.58 | 0.93 | | 草地→旱地 | 62 | -3.60 | -0.44 | 0.72 | | 水田-水田 | 118 | 1.43 | -0.08 | 0.92 |
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Changes of soil SOC, TN and C/N contents in main reclamation types
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