粉垄耕作对平地和坡耕地蔗田土壤有机碳矿化和结构的影响

doi:10.3969/j.issn.1000-6362.2020.05.004

摘要/Abstract

摘要： 2018-2019年在广西南宁丘陵山区甘蔗田采用雨养模式，设置粉垄耕作与常规耕作两种耕作方式，开展平地和坡耕地甘蔗田间试验。试验在甘蔗全生育期不进行人工灌溉，收获期采集0-15cm耕层及15-30cm耕层土壤样品，用土壤紧实度仪多点位测定0-45cm深度土壤紧实度，利用湿筛法测定土壤团聚体，应用室内恒温培养-碱液吸收法测定土壤有机碳矿化量，以探索粉垄耕作对坡耕地雨养蔗田土壤有机碳矿化速率、累积矿化量及土壤团聚体与紧实度结构效应的影响。结果表明：（1）平地蔗田土壤有机碳累积矿化量始终高于坡耕地，粉垄耕作处理下，平地0-15cm和15-30cm耕层土壤有机碳矿化量较坡耕地分别提高0.32倍和1.05倍；坡耕地蔗田土壤0-15cm和15-30cm耕层有机碳7日累积矿化量粉垄耕作比常规耕作升高81.7%和降低7.5%，平地上则降低8.4%和升高2.6%；（2）与常规耕作方式相比，粉垄耕作提高了蔗田土壤大团聚体含量，平地和坡耕地分别增加5.53%和2.30%，平地土壤大团聚体含量为坡耕地的1.00～1.03倍，粉垄耕作降低了蔗田土壤中小、微团聚体含量。同时，粉垄耕作提高了土壤水稳性团聚体平均质量直径（MWD）和几何平均直径（GMD），与常规耕作相比，平地和坡耕地MWD分别提高15.6%和58.7%，GMD分别提高31.4%和48.1%。同种耕作模式下平地土壤水稳性团聚体的MWD值和GMD值均高于坡耕地，平地常规耕作和粉垄耕作土壤MWD值较坡耕地分别提高1.19和0.60倍，平地常规耕作和粉垄耕作土壤GWD值较坡耕地分别提高0.99 和0.77倍；（3）粉垄耕作方式对坡耕地蔗田土壤紧实度的影响比平地大，粉垄耕作降低了蔗田土壤紧实度，且15-30cm耕层影响较明显。因此，粉垄雨养甘蔗提高了平地和坡耕地土壤耕层碳存储，可降低土壤紧实度，增加土壤大团聚体形成，优化土壤耕层结构，该模式可作为南方蔗田土壤干旱逆境调控技术措施。

关键词: , 粉垄, 坡耕地, 土壤矿化, 土壤团聚体, 蔗田

Abstract: It is the main way of rain-fed sugarcane in smash ridging production in hilly areas of south China. In order to explore the effects of slope farmland on the mineralization rate, accumulation of mineralization, soil aggregates and compact-degree structure of rain-raised sugarcane soil. In 2018-2019, smash ridging and conventional tillage were adopted in Nanning, Guangxi. Field positioning experiments were carried out on flat land and sloping farmland with no artificial irrigation during the whole growth period. Soil samples were collected in the 0-15cm topsoil and 15-30cm topsoil during the harvest period of sugarcane, and soil compactness meter was used to measure soil compactness at a depth of 0-45cm at multiple points. Soil aggregates were determined by wet sieve method. The content of soil organic carbon mineralization was determined by indoor constant temperature culture-alkali absorption method. The results showed that, (1)the soil organic carbon accumulative mineralization of rain-fed sugarcane soil in flat land is always higher than that in sloping farmland, the soil organic carbon mineralization in the 0-15cm topsoil and 15-30cm topsoil of the flat land under smash ridging was 0.32 and 1.05 times higher than that in the sloping farmland, respectively. The cumulative mineralization of organic carbon in the 0-15cm topsoil and the 15-30cm topsoil of the sugarcane field increased and decreased by 81.7% and 7.5%, respectively, and decreased and increased by 8.4% and 2.6%, respectively, in the flat land. (2)The content of large aggregates in the soil of rain-fed sugarcane was increased by smash ridging. Flat land and sloping land increased by 5.53 and 5.30 percent respectively. The content of large aggregates in flat soil was 1.00-1.03 times of that in sloping farmland. On the contrary, smash ridging reduced the content of small and micro aggregates in rain-fed sugarcane. The average mean weight diameter (MWD) and geometric mean diameter (GMD) of soil water stable aggregates were improved by smash ridging. Compared with conventional cultivated plain land and sloping farmland, MWD increased 15.6% and 58.7%, respectively, and GMD increased 31.4% and 48.1%, respectively. The MWD and GMD values of soil water stability aggregates in the same tillage mode were higher than those of sloping farmland. The MWD values of flat land conventional tillage and smash ridging tillage were 1.19 and 0.60 times higher than that of slope farmland respectively, and the GWD values of flat land conventional tillage and smash ridging tillage were 0.99 and 0.77 times higher than that of slope farmland respectively. (3)The soil compactness of rain-fed sugarcane was affected by smash ridging more than that of plain field. The soil compactness of rain-fed sugarcane was decreased by smash ridging, and the effect was most obvious at 15-30cm. Therefore, rain-fed sugarcane in smash ridging improves the carbon storage in the topsoil of flat land and slope farmland, reduce soil compactivity, increase the formation of large aggregates, and optimize the topsoil structure. This model can be used as a technical measure to control drought and stress in sugarcane fields in southern China.

Key words: Smash ridging, Slope farmland, Soil mineralization, Soil aggregate, Sugarcane field

中图分类号:

陈仕林，胡钧铭，黄忠华，李婷婷，郑佳舜，黄俞铭，罗维钢，何铁光，韦翔华. 粉垄耕作对平地和坡耕地蔗田土壤有机碳矿化和结构的影响[J]. 中国农业气象, 2020, 41(05): 299-307.

CHEN Shi-lin, HU Jun-ming, LI Ting-ting, HUANG Zhong-hua, ZHENG Jia-shun, HUANG Yu-ming, Luo Wei-gang, HE Tie-guang,WEI Xiang-hua. Effects of Smash Ridging on Soil Organic Carbon Mineralization and Structure of Sugarcane Field in Flat and Slope Farmland [J]. Chinese Journal of Agrometeorology, 2020, 41(05): 299-307.

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