Effects of Different Winter Cover Crop Rotations on Farmland Soil Carbon and Nitrogen

doi:10.11924/j.issn.1000-6850.casb2021-0042

Abstract

Abstract:

Wind erosion is a key factor of soil quality reduction in agro-ecosystems in arid area, and winter crop coverage can effectively reduce soil wind erosion. This study aims to construct a suitable annual cover crop rotation pattern based on the effect of different winter cover crop rotations integrated with green manure multiple cropping on soil carbon and nitrogen in Hexi irrigation area. A field experiment was carried out in spring wheat region of Hexi irrigation area where the temperature conditions were surplus for one season of crop but insufficient for two seasons of crop. The experiment was conducted with four rotation patterns of nested planting (WCP: spring wheat—winter rape—common vetch; WWP: spring wheat—winter wheat—common vetch; WP: spring wheat—common vetch; W and CK: spring wheat—spring wheat) and three nitrogen levels (N2: 360 kg/hm², N1: 270 kg/hm², N0: 0 kg/hm²). The effects of different crop rotation patterns on soil carbon and nitrogen content were analyzed. The results showed that the content of soil organic carbon, soil soluble organic carbon, thermally extracted organic carbon, nitrate nitrogen, ammonia nitrogen and microbial biomass carbon and nitrogen increased with the nitrogen application rate under the same rotation pattern. In WCP rotation mode, N1 did not decrease the content of soil organic carbon, soil soluble organic carbon, soil thermally extracted organic carbon and microbial biomass nitrogen, respectively, compared with N2. Under the condition of the same nitrogen application rate, the difference among the rotation patterns was not significant, but they significantly differed from CK. Among them, in 0-10 cm soil layer, WCP rotation mode increased the average content of soil organic carbon, soil soluble organic carbon, soil thermally extracted organic carbon, nitrate nitrogen, ammonia nitrogen, microbial biomass carbon and nitrogen by 5.42%, 9.78%, 10.96%, 20.51%, 15.76%, 18.94% respectively compared with CK; in 10-30 cm soil layer, the above indexes increased by 9.54%, 7.06%, 12.99%, 20.12%, 16.51%, 18.16%, respectively. Therefore, under the condition of nitrogen reduction, the spring wheat and winter rape rotation integrated with green manure multiple cropping pattern (WCP) has significant effect on improving farmland soil carbon and nitrogen, which is an appropriate annual cover crop rotation pattern in Hexi irrigation area.

Key words: crop rotation, winter mulch, winter rape, green manure, soil organic carbon

CLC Number:

S344

Ren Hui, Ding Lei, Zhao Cai. Effects of Different Winter Cover Crop Rotations on Farmland Soil Carbon and Nitrogen[J]. Chinese Agricultural Science Bulletin, 2021, 37(35): 57-64.

Figures/Tables 7

References 30

[1]	延昊, 王绍强, 王长耀, 等. 风蚀对中国北方脆弱生态系统碳循环的影响[J]. 第四纪研究, 2004(6):672-677.
[2]	赵哈林, 周瑞莲, 苏永中, 等. 我国北方半干旱地区土壤的沙漠化演变过程与机制[J]. 水土保持学报, 2007(3):1-5.
[3]	Zhao H L, Zhou R L, Zhang T H, et al. Effects of desertiﬁcation on soil and crop growth properties in Horqin sandy cropland of Inner Mongolia, north China[J]. Soil and Tillage Research, 2006, 87(2):175-185. doi: 10.1016/j.still.2005.03.009 URL
[4]	黄高宝, 于爱忠, 郭清毅, 等. 甘肃河西冬小麦保护性耕作对土壤风蚀影响的风洞试验研究[J]. 土壤学报, 2007(6):968-973.
[5]	张小燕. 西北地区植被背景值及演替规律研究[D]. 杨凌:西北农林科技大学, 2003.
[6]	Godfray H C, Beddington J R, Crute I R, et al. Food Security: The Challenge of Feeding 9 Billion People[J]. Science, 2010, 327(5967):812-818. doi: 10.1126/science.1185383 URL
[7]	Seto K C, Ramankutty N. Hidden linkages between urbanization and food systems[J]. Science, 2016, 352(6288):943-945. doi: 10.1126/science.aaf7439 URL
[8]	赵月, 王春雨, 隋跃宇, 等. 基于玉米大豆轮作的黑土玉米农田酶活性对不同耕层厚度的响应[J]. 玉米科学, 2019, 27(6):95-103.
[9]	吴鹏博, 李立军, 张艳丽, 等. 轮作结合施肥对土壤有机碳及其组分和土壤养分的影响[J]. 土壤通报, 2020, 51(2):416-422.
[10]	张顺涛, 鲁剑巍, 丛日环, 等. 油菜轮作对后茬作物产量的影响[J]. 中国农业科学, 2020, 53(14):2852-2858.
[11]	赵娜, 赵护兵, 鱼昌为, 等. 夏闲期种植翻压绿肥和施氮量对冬小麦生长的影响[J]. 西北农业学报, 2010, 19(12):41-47.
[12]	张达斌, 李婧, 姚鹏伟, 等. 夏闲期连续两年种植并翻压豆科绿肥对旱地冬小麦生长和养分吸收的影响[J]. 西北农业学报, 2012, 21(1):59-65.
[13]	魏静, 郭树芳, 孙本华, 等. 冬季覆盖作物对潮褐土土壤肥力和微生物学性状的影响[J]. 生态与农村环境学报, 2018, 34(5):426-432.
[14]	鲍士旦. 土壤农化分析[M]. 北京: 中国农业出版社, 2000:25-108
[15]	张晋京, 窦森. 土壤胡敏素研究进展[J]. 生态学报, 2008(3):1229-1239.
[16]	傅积平. 土壤结合态腐殖质分组测定[J]. 土壤通报, 1983(2):36-37.
[17]	俞慎, 李振高. 薰蒸提取法测定土壤微生物量研究进展[J]. 土壤学进展, 1994, 22(6):42-50.
[18]	杨尚东, 李荣坦, 吴俊. 番茄连作与轮作土壤生物学特性及细菌群落结构的比较[J]. 生态环境学报, 2016, 25(1):76-83
[19]	付仲毅, 张晓远, 张晓帆, 等. 烤烟连作对植烟土壤碳库及烤后烟叶品质的影响[J]. 西北农林科技大学学报:自然科学版, 2018, 46(8):16-22.
[20]	虎德钰, 毛桂莲, 许兴. 不同草田轮作方式对土壤微生物和土壤酶活性的影响[J]. 西北农业学报, 2014, 2(9):106-113.
[21]	Humberto B C, Sabrina J R. Cover crop impacts on soil physical properties: A review[J]. Soil Science Society of America Journal, 2020, 84(5):1527-1576. doi: 10.1002/saj2.v84.5 URL
[22]	朱波, 胡跃高, 曾昭海. 双季稻区冬种覆盖作物对土壤微生物量的影响[J]. 生态环境, 2008, 17(5):2074-2077.
[23]	郭胜利, 吴金水, 党廷辉. 轮作和施肥对半干旱区作物地上部生物量与土壤有机碳的影响[J]. 中国农业科学, 2008(3):744-751.
[24]	谢志坚, 徐昌旭, 许政良, 等. 翻压等量紫云英条件下不同化肥用量对土壤养分有效性及水稻产量的影响[J]. 中国土壤与肥料, 2011(4):79-82.
[25]	李宏图, 罗建新, 彭德元, 等. 绿肥翻压还土的生态效应及其对土壤主要物理性状的影响[J]. 中国农学通报, 2013, 29(5):172-175.
[26]	蔡常被. 水田油菜用地养地初步调查研究[J]. 湖北农业科学, 1978(8):12-13.
[27]	Getachew A, Berhane L, Paul N. Cropping sequence and nitrogen fertilizer effects on the productivity and quality of malting barley and soil fertility in the Ethiopian highlands[J]. Archives of Agronomy and Soil Science, 2014, 60(9):1261-1275. doi: 10.1080/03650340.2014.881474 URL
[28]	王学芳, 孙万仓, 李孝泽, 等. 河西走廊种植冬油菜的环境效应[J]. 作物学报, 2008, 34(12):2210-2217. doi: 10.3724/SP.J.1006.2008.02210
[29]	刘晓伟, 鲁剑巍, 李小坤, 等. 冬油菜叶片的物质及养分积累与转移特性研究[J]. 植物营养与肥料学报, 2011, 17(4):956-963.
[30]	杨瑞吉, 马海灵, 杨祁峰, 等. 种植密度与施氮量对麦茬复种饲料油菜土壤微生物活性的影响[J]. 应用生态学报, 2007(1):113-117.

施氮及种植模式		硝态氮		氨态氮
施氮及种植模式		0~10 cm	10~30 cm	0~10 cm	10~30 cm
N2	WCP	26.54a	14.89a	10.91a	10.20a
	WWP	22.53b	14.23ab	10.84a	9.72ab
	WP	22.96b	15.26a	10.42ab	9.93ab
	W	22.46b	13.07b	9.77b	8.99b
N1	WCP	21.59b	12.08b	9.76b	8.94b
	WWP	21.40bc	11.91bc	9.27bc	8.70b
	WP	21.99b	12.66b	8.89c	8.52bc
	W	20.38c	11.19c	8.57d	7.33cd
N0	WCP	19.57c	11.88bc	8.84cd	7.82c
	WWP	18.31c	9.79bc	8.54cd	6.94cd
	WP	19.78c	10.32c	8.07d	6.54d
	W	13.33d	8.07d	7.15e	5.79e

施氮及种植模式		硝态氮		氨态氮
施氮及种植模式		0~10 cm	10~30 cm	0~10 cm	10~30 cm
N2	WCP	26.54a	14.89a	10.91a	10.20a
	WWP	22.53b	14.23ab	10.84a	9.72ab
	WP	22.96b	15.26a	10.42ab	9.93ab
	W	22.46b	13.07b	9.77b	8.99b
N1	WCP	21.59b	12.08b	9.76b	8.94b
	WWP	21.40bc	11.91bc	9.27bc	8.70b
	WP	21.99b	12.66b	8.89c	8.52bc
	W	20.38c	11.19c	8.57d	7.33cd
N0	WCP	19.57c	11.88bc	8.84cd	7.82c
	WWP	18.31c	9.79bc	8.54cd	6.94cd
	WP	19.78c	10.32c	8.07d	6.54d
	W	13.33d	8.07d	7.15e	5.79e