Variation Characteristics of Organic Carbon in Arable Black Soil in Suihua City

doi:10.11924/j.issn.1000-6850.casb2022-0074

Abstract

Abstract:

To explore the variation characteristics of organic carbon of arable black soil in Suihua City of Heilongjiang Province, the content of soil organic carbon in 2002 and 2019 were compared to clarify the temporal and spatial variation characteristics of organic carbon. The results showed that the average organic carbon content of arable black soil in Suihua City in 2002 was 22.02 g/kg, and the coefficient of variation was 22.57%. The average organic carbon content in 2019 was 21.67 g/kg, and the coefficient of variation was 22.47%. The organic carbon content in 2002 and 2019 belonged to medium variation. The average organic carbon content only increased in Wangkui County and Beilin District, by 2.96 g/kg and 0.13g/kg, respectively. The average organic carbon content in Lanxi County, Suiling County, Qing’an County, Qinggang County, Hailun City and Mingshui County decreased by 1.91, 1.72, 1.45, 0.46, 0.44 and 0.32 g/kg, respectively. According to the nutrient classification standard, the organic carbon content in Suihua was at the third and fourth level in 2002 and 2019. In view of the spatial variation, the organic carbon first decreased then increased from both sides to the middle and increased gradually from south to north. From 2002 to 2019, the organic carbon content of arable black soil in Suihua showed a downward trend, the nutrient classification of organic carbon did not change in the 17 years and the spatial distribution trend of organic carbon did not change significantly.

Key words: Suihua City, arable black soil, organic carbon, distribution characteristics, spatial heterogeneity

CLC Number:

S153.6+21

LIU Wanling, WANG Junjie, LIN Zijun, ZENG Ting, CHEN Yimin, SUI Yueyu, JIAO Xiaoguang. Variation Characteristics of Organic Carbon in Arable Black Soil in Suihua City[J]. Chinese Agricultural Science Bulletin, 2022, 38(20): 67-72.

Figures/Tables 5

References 29

[1]	辛景树, 汪景宽, 薛彦东. 东北黑土区耕地质量评价[M]. 北京: 中国农业出版社, 2017.
[2]	汪景宽, 徐香茹, 裴久渤, 等. 东北黑土地区耕地质量现状与面临的机遇和挑战[J]. 土壤通报, 2021, 52(3):695-701.
[3]	赵军, 张久明, 孟凯, 等. 地统计学及GIS在黑土区域土壤养分空间异质性分析中的应用——以海伦市为例[J]. 水土保持通报, 2004(6):53-57.
[4]	宁静, 王婷, 刘佳会, 等. 东北典型黑土区土壤养分的空间分布特征及影响因素——以黑龙江省宾县为例[J]. 西安:西安理工大学学报, 2021, 37(3):301-310.
[5]	杨玉玲, 文启凯, 田长彦, 等. 土壤空间变异研究现状及展望[J]. 干旱区研究, 2001(2):50-55.
[6]	刘书田. 中国农田土壤有机碳时空分布规律及影响因素研究[D]. 长春: 吉林农业大学, 2016.
[7]	韩晓增, 王守宇, 宋春雨, 等. 土地利用/覆盖变化对黑土生态环境的影响[J]. 地理科学, 2005(2):203-208.
[8]	于磊, 张柏. 中国黑土退化现状与防治对策[J]. 干旱区资源与环境, 2004(1):99-103.
[9]	邹文秀, 韩晓增, 陆欣春, 等. 肥沃耕层构建对东北黑土区旱地土壤肥力和玉米产量的影响[J]. 应用生态学报, 2020, 31(12):4134-4146. doi: 10.13287/j.1001-9332.202012.030
[10]	韩秉进, 张旭东, 隋跃宇, 等. 东北黑土农田养分时空演变分析[J]. 土壤通报, 2007(2):238-241.
[11]	陆访仪, 赵永存, 黄标, 等. 近30年来海伦市耕地土壤有机质和全氮的时空演变[J]. 土壤, 2012, 44(1):42-9
[12]	尤孟阳, 郝翔翔, 李禄军. 海伦黑土有机碳和养分含量30年变化特征[J]. 土壤与作物, 2020, 9(3):211-220.
[13]	郑琳. 海伦市近30年农田黑土碳储量及其时空变化[D]. 哈尔滨: 东北农业大学, 2015.
[14]	宋丹. 东北区耕地土壤有机质现状、演变趋势及改良对策[J]. 辽宁农业科学, 2021(5):66-69.
[15]	谭琴, 童蕾, 马乃进, 等. 海伦市耕地表层黑土中有机碳与不同矿物态铁的空间分布特征及其相关关系[J]. 安全与环境工程, 2020, 27(06):23-30.
[16]	SUN B, ZHOU S, ZHAO Q. Evaluation of spatial and temporal changes of soil quality based on geostatistical analysis in the hill region of subtropical China. Geoderma, 2003, 115(Suppl.1/2):85-99. doi: 10.1016/S0016-7061(03)00078-8 URL
[17]	BORGES R, MALLARINO A P. Field-scale variability of phosphorus and potassium uptake by no-till corn and soybean. Soil Science Society of America Journal, 1997, 61(3):846-853. doi: 10.2136/sssaj1997.03615995006100030019x URL
[18]	王俊杰. 绥化市典型农田黑土土壤碳氮时空分布特征[D]. 哈尔滨: 黑龙江大学, 2021.
[19]	张冰洁, 宋戈. 松嫩高平原黑土区典型地域耕地生态安全评价及驱动力分析——以黑龙江省绥化市为例[J]. 水土保持研究, 2012, 19(03):215-220.
[20]	杨佳佳, 白磊, 吴嵩. 黑龙江典型黑土区土壤侵蚀遥感监测技术研究[J]. 地质与资源. 2019, 28(2):193-199.
[21]	温东亮. 绥化市寒地黑土可持续开发利用研究[D]. 长春: 吉林大学, 2010.
[22]	裴巍. 区域农业旱灾风险评价及时空变异研究[D]. 哈尔滨: 东北农业大学, 2017.
[23]	车升国. 区域作物专用复合(混)肥料配方制定方法与应用[D]. 北京: 中国农业大学, 2015.
[24]	SÖDERLUND R, SVENSSON B H. The Global Nitrogen Cycle[J]. Ecological bulletins, 1976, 451(22):23-73.
[25]	MALLARINO A P. Spatial variability patterns of phosphorus and potassium in no-tilled soils for two sampling scales[J]. Soil science society of american journal, 1996, 60:1473-1481. doi: 10.2136/sssaj1996.03615995006000050027x URL
[26]	ESWARAN H, BERG E V D, REICH P. Organic Carbon in Soils of the World[J]. Soil science society of america journal, 1993, 1(57):192-194.
[27]	CAMPBELL J B. Spatial Variation of Sand Content and p H Within Single Contiguous Delineations of Two Soil Mapping Units[J]. Soil science society of america journal, 1978, 42(3):460-464. doi: 10.2136/sssaj1978.03615995004200030017x URL
[28]	FRENCH N R, STEINHORST R K, SWIFT D M. Grassland Biomass Trophic Pyramids[M]. Perspectives in grassland ecology, Springer-verlag,New York. 1979:59-87.
[29]	BOUWMAN A F. Global distribution of the major soils and land cover types[M]. Soils and the greenhouse effect, New York. 1990:33-59.

区域	2002年土壤有机碳					2019年土壤有机碳
区域	最小值/ (g/kg)	最大值/ (g/kg)	平均值/ (g/kg)	标准差	变异系数/ %	最小值/ (g/kg)	最大值/ (g/kg)	平均值/ (g/kg)	标准差	变异系数/ %
绥化	10.66	35.85	22.02	4.97	22.57	11.48	36.39	21.67	4.87	22.47
明水	16.97	24.78	21.7	2.46	11.35	15.88	25.20	21.38	2.52	11.77
海伦	15.36	35.85	26.19	5.7	21.75	17.62	36.39	25.75	5.19	20.17
绥棱	10.66	31.77	24.33	8.13	33.42	14.66	31.41	22.61	7.46	33.01
庆安	19.07	30.43	23.34	3.59	15.37	11.48	29.63	21.89	6.67	30.46
青冈	17.44	24.32	20.93	2.31	11.04	16.35	23.44	20.47	2.03	9.91
望奎	17.42	21.93	19.77	1.53	7.72	18.32	30.60	22.73	4.19	18.42
北林	14.9	23.39	18.51	2.2	11.91	13.82	24.44	18.64	1.91	10.24
兰西	15.71	22.19	19.33	2.2	11.4	14.71	20.10	17.42	1.38	7.93

区域	2002年土壤有机碳					2019年土壤有机碳
区域	最小值/ (g/kg)	最大值/ (g/kg)	平均值/ (g/kg)	标准差	变异系数/ %	最小值/ (g/kg)	最大值/ (g/kg)	平均值/ (g/kg)	标准差	变异系数/ %
绥化	10.66	35.85	22.02	4.97	22.57	11.48	36.39	21.67	4.87	22.47
明水	16.97	24.78	21.7	2.46	11.35	15.88	25.20	21.38	2.52	11.77
海伦	15.36	35.85	26.19	5.7	21.75	17.62	36.39	25.75	5.19	20.17
绥棱	10.66	31.77	24.33	8.13	33.42	14.66	31.41	22.61	7.46	33.01
庆安	19.07	30.43	23.34	3.59	15.37	11.48	29.63	21.89	6.67	30.46
青冈	17.44	24.32	20.93	2.31	11.04	16.35	23.44	20.47	2.03	9.91
望奎	17.42	21.93	19.77	1.53	7.72	18.32	30.60	22.73	4.19	18.42
北林	14.9	23.39	18.51	2.2	11.91	13.82	24.44	18.64	1.91	10.24
兰西	15.71	22.19	19.33	2.2	11.4	14.71	20.10	17.42	1.38	7.93

区域	均值变化率	变异系数增幅
绥化市	-1.6	-0.1
明水	-1.47	0.42
海伦	-1.68	-1.58
绥棱	-7.07	-0.41
庆安	-6.21	15.09
青冈	-2.2	-1.13
望奎	14.97	10.7
北林	0.7	-1.67
兰西	-9.88	-3.47

区域	均值变化率	变异系数增幅
绥化市	-1.6	-0.1
明水	-1.47	0.42
海伦	-1.68	-1.58
绥棱	-7.07	-0.41
庆安	-6.21	15.09
青冈	-2.2	-1.13
望奎	14.97	10.7
北林	0.7	-1.67
兰西	-9.88	-3.47