Xinjiang Agricultural Sciences ›› 2022, Vol. 59 ›› Issue (2): 441-450.DOI: 10.6048/j.issn.1001-4330.2022.02.022
• Prataculture·Storage and Preservation Processing·Microbes • Previous Articles Next Articles
WANG Weixia(), Aliya Alimu, YANG Guang, WANG Zhenxi
Received:
2021-01-20
Online:
2022-02-20
Published:
2022-03-22
Correspondence author:
WANG Weixia
Supported by:
通讯作者:
王卫霞
作者简介:
王卫霞 (1981-),女,新疆乌鲁木齐人,副教授,博士,研究方向为森林生态与经营, (E-mail) wangweixia0993@163.com
基金资助:
CLC Number:
WANG Weixia, Aliya Alimu, YANG Guang, WANG Zhenxi. Effects of Land Use Patterns on Soil Liable Organic Carbon and Dissolved Organic Carbon in Typical Arid Desert Oasis Area[J]. Xinjiang Agricultural Sciences, 2022, 59(2): 441-450.
王卫霞, 阿丽娅·阿力木, 杨光, 王振锡. 干旱荒漠绿洲区不同土地利用方式对土壤易氧化及溶解性有机碳的影响[J]. 新疆农业科学, 2022, 59(2): 441-450.
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土地利用方式 Land use types | 最小值 Minimum (g/kg) | 最大值 Maximum (g/kg) | 平均值 Mean (g/kg) | 标准差 Std.Deviation | 变异系数 Coefficient of variation(%) |
---|---|---|---|---|---|
小麦 Wheat | 0.74 | 5.85 | 3.83±0.38A | 1.73 | 45 |
枣园 Jujube | 2.2 | 11.2 | 6.02±0.65B | 2.98 | 50 |
枣麦间作 Jujube-Wheat intercropping | 1.87 | 10.85 | 5.66±0.69B | 3.14 | 56 |
总体 Total | 0.74 | 11.2 | 5.17±0.36 | 2.82 | 55 |
Table 1 Descriptive statistics of total organic carbon content of 0-100 cm under different land use types
土地利用方式 Land use types | 最小值 Minimum (g/kg) | 最大值 Maximum (g/kg) | 平均值 Mean (g/kg) | 标准差 Std.Deviation | 变异系数 Coefficient of variation(%) |
---|---|---|---|---|---|
小麦 Wheat | 0.74 | 5.85 | 3.83±0.38A | 1.73 | 45 |
枣园 Jujube | 2.2 | 11.2 | 6.02±0.65B | 2.98 | 50 |
枣麦间作 Jujube-Wheat intercropping | 1.87 | 10.85 | 5.66±0.69B | 3.14 | 56 |
总体 Total | 0.74 | 11.2 | 5.17±0.36 | 2.82 | 55 |
土地利用方式 Land use types | 土壤深度 Soil depth(cm) | 土壤总有机碳 TOC (g/kg) | 有机碳组分占有机碳的比例(%) | |
---|---|---|---|---|
LOC /TOC | DOC/TOC | |||
0~10 | 5.74±0.09Aa | 28.23 | 5.75 | |
10~20 | 5.4±0.11Aa | 21.62 | 4.28 | |
小麦 | 20~30 | 4.95±0.08Aab | 17.53 | 3.72 |
Wheat | 30~40 | 3.76±0.66Abc | 19.78 | 5.20 |
40~60 | 3.26±0.77Acd | 14.18 | 6.85 | |
60~80 | 2.13±0.73Ade | 14.26 | 7.08 | |
80~100 | 1.48±0.52Ac | 13.18 | 9.06 | |
0~10 | 9.56±1.40Ba | 22.26 | 4.63 | |
10~20 | 8.88±1.21Ba | 21.22 | 4.08 | |
枣园 | 20~30 | 7.97±1.22Bab | 15.84 | 4.25 |
Jujube | 30~40 | 5.26±1.23Abc | 18.07 | 5.69 |
40~60 | 4.14±0.67Ac | 16.50 | 7.04 | |
60~80 | 3.36±0.44Ac | 12.74 | 6.47 | |
80~100 | 2.99±0.47Bc | 8.43 | 6.83 | |
0~10 | 10.59±0.19Ba | 20.30 | 5.59 | |
10~20 | 8.76±0.82Bb | 20.25 | 4.69 | |
枣麦间作 | 20~30 | 7.03±0.88Bc | 21.52 | 5.33 |
Jujube~Wheat intercropping | 30~40 | 4.68±0.33Ad | 22.49 | 6.58 |
40~60 | 3.73±0.66Ade | 22.00 | 6.94 | |
60~80 | 2.58±0.31Ae | 17.04 | 9.65 | |
80~100 | 2.28±0.27ABe | 13.85 | 7.98 |
Table 2 Soil organic carbon content and distribution ratio of active organic carbon components
土地利用方式 Land use types | 土壤深度 Soil depth(cm) | 土壤总有机碳 TOC (g/kg) | 有机碳组分占有机碳的比例(%) | |
---|---|---|---|---|
LOC /TOC | DOC/TOC | |||
0~10 | 5.74±0.09Aa | 28.23 | 5.75 | |
10~20 | 5.4±0.11Aa | 21.62 | 4.28 | |
小麦 | 20~30 | 4.95±0.08Aab | 17.53 | 3.72 |
Wheat | 30~40 | 3.76±0.66Abc | 19.78 | 5.20 |
40~60 | 3.26±0.77Acd | 14.18 | 6.85 | |
60~80 | 2.13±0.73Ade | 14.26 | 7.08 | |
80~100 | 1.48±0.52Ac | 13.18 | 9.06 | |
0~10 | 9.56±1.40Ba | 22.26 | 4.63 | |
10~20 | 8.88±1.21Ba | 21.22 | 4.08 | |
枣园 | 20~30 | 7.97±1.22Bab | 15.84 | 4.25 |
Jujube | 30~40 | 5.26±1.23Abc | 18.07 | 5.69 |
40~60 | 4.14±0.67Ac | 16.50 | 7.04 | |
60~80 | 3.36±0.44Ac | 12.74 | 6.47 | |
80~100 | 2.99±0.47Bc | 8.43 | 6.83 | |
0~10 | 10.59±0.19Ba | 20.30 | 5.59 | |
10~20 | 8.76±0.82Bb | 20.25 | 4.69 | |
枣麦间作 | 20~30 | 7.03±0.88Bc | 21.52 | 5.33 |
Jujube~Wheat intercropping | 30~40 | 4.68±0.33Ad | 22.49 | 6.58 |
40~60 | 3.73±0.66Ade | 22.00 | 6.94 | |
60~80 | 2.58±0.31Ae | 17.04 | 9.65 | |
80~100 | 2.28±0.27ABe | 13.85 | 7.98 |
Fig.1 Distribution characteristics of liable organic carbon and non-liable organic carbon content under different land use types Notes: Different lowercase letters in the same column indicate that the difference in different land use types is significant (P<0.05),the same as below
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