留膜留茬免耕栽培对旱作玉米田土壤养分、微生物数量及酶活性的影响

doi:10.11686/cyxb2019403

摘要/Abstract

摘要： 为了探讨不同耕作和覆盖方式对陇东黄土旱塬农田耕层土壤养分、土壤容重、酶活性及微生物数量的影响。采用随机区组设计,设置留膜留茬免耕栽培(T)和全膜双垄沟播栽培(CK)2个处理,测定不同生育时期0~10 cm、10~20 cm、20~40 cm 3个土层土壤养分含量、水解酶(蔗糖酶、脲酶、磷酸酶、过氧化氢酶)活性及微生物(细菌、放线菌、真菌)数量等指标。结果表明:与 CK 相比,留膜留茬免耕栽培显著(P<0.05)提高了收获期表层(0~10 cm)土壤有机质、全量磷钾及速效磷钾含量,随土层深度增加,有机质及全量和速效磷钾含量均呈递减趋势。碱解氮含量在0~20 cm土层降低,在20~40 cm土层出现聚集。留膜留茬免耕栽培显著(P<0.05)增加了0~10 cm、10~20 cm、20~30 cm土层土壤容重,增幅为7.1%~12.4%。不同耕作方式玉米0~40 cm土层微生物数量为细菌>放线菌>真菌。耕作方式对不同土层各生育期土壤微生物数量整体上影响显著(P<0.05),为T>CK。同一生育期随土层深度增加,土壤微生物数量整体上呈减少趋势,以表层(0~10 cm)最高,为T>CK。与CK相比,T的细菌和真菌在苗期、拔节期、抽雄期、灌浆期、收获期分别增加23.7%、64.5%、7.6%、44.0%、5.6%和31.1%、91.7%、85.7%、10.5%、33.3%。放线菌在苗期、拔节期、收获期分别增加79.8%、15.1%、17.6%,抽雄期、灌浆期分别减少17.2%、33.2%。耕作方式对不同土层各生育期土壤酶活性整体上影响显著(P<0.05),为T>CK。同一生育期随土层深度增加,酶活性逐渐降低,以表层(0~10 cm)最高,T效果优于CK,与CK相比,T的蔗糖酶、脲酶、磷酸酶、过氧化氢酶在玉米全生育期增幅分别为4.7%~126.1%、9.8%~47.0%、5.4%~33.7%、2.3%~43.2%。相关分析表明:土壤酶活性之间呈显著(P<0.05)或极显著(P<0.01)相关,细菌与蔗糖酶显著(P<0.05)相关,与磷酸酶极显著(P<0.01)相关,放线菌与土壤酶活性呈显著(P<0.05)或极显著(P<0.01)相关,表明土壤微生物数量与酶活性能较好地反映土壤肥力水平。因此,留膜留茬免耕栽培在旱作农田条件下有利于土壤有机质及磷钾养分含量、酶活性及微生物数量的提高。

关键词: 留膜留茬免耕栽培, 旱作农田, 土壤酶活性, 土壤养分, 土壤微生物数量

Abstract: The objective of this study was to investigate the effect of different tillage and mulching methods on soil nutrients, soil bulk density, enzyme activity and microbial populations in the tillage layer in arid croplands of eastern Gansu Province, China. The experiments included a no-tillage treatment with residues of film (T) and a double ridge plastic film mulching treatment (CK) and used a randomized block design. Soil nutrient levels, hydrolase enzyme activities (sucrose, urease, phosphatase, catalase), and microorganism abundance (bacteria, actinomycetes, fungi) were compared in the two treatments. It was found that compared with CK, the T treatment significantly increased the soil organic matter by 7.8%, total phosphorus by 11.3%, total potassium by 3.7%, available phosphorus by 12.7% and available potassium by 6.1% in the 0-10 cm soil layer at crop harvest. These indicators decreased with increase in soil depth. The alkali nitrogen content of the T treatment in the 0-20 cm soil layer was lower than in the CK treatment. However, in the 20-40 cm soil layer, the alkaline nitrogen content was high in the T treatment. The T treatment significantly increased the bulk density by 7.1%-12.4% in the 0-30 cm soil layer. In the 0-40 cm soil layer, the most abundant microorganisms were bacteria, followed by actinomycetes, with fungi the least abundant. The tillage treatments affected soil microbial populations differently at different crop growth stages. For a given crop growth stage, the soil microbial abundance decreased with increase in soil depth, especially in the T treatment. Compared with CK, the T treatment increased bacterial abundance by 23.7%, 64.5%, 7.6%, 44.0%, 5.6% at the seedling, jointing, flowering, grain filling and harvesting growth stages, respectively. The T treatment also increased fungal abundance by 31.1%, 91.7%, 85.7%, 10.5%, 33.3%, respectively, at the same five growth stages, and increased actinomycete abundance by 79.8%, 15.1% and 17.6% at seedling, jointing, and harvesting growth stages, respectively, and decreased actinomycete abundance by 17.2% at flowering and 33.2% at the grain fill growth stage. The tillage method also had a significant impact on soil enzyme activity in different soil layers. At any given crop growth stage, the soil enzyme activity decreased with increase in soil depth, and this pattern was more pronounced in the T treatment. The activities of sucrase, urease, phosphatase and catalase were increased in the T treatment by 4.7%-126.1%, 9.8%-47.0%, 5.4%-33.7% and 2.3%-43.2%, respectively, compared to the CK treatment, over the crop development cycle. Significant positive correlations were found among the activity values of the various enzymes, and also between enzyme activities and numbers of microorganisms. Hence, these results indicate that soil enzyme activities and microorganism abundance could be considered good indicators of soil fertility level. In summary, no-tillage with residues of film and stubble was beneficial to improve the soil nutrient content, microbial abundance and enzyme activity in dryland cropping fields.

Key words: no-tillage with residues of film and stubble, dryland, soil enzyme activity, soil nutriment, soil microbial quantity

张建军, 党翼, 赵刚, 王磊, 樊廷录, 李尚中, 雷康宁. 留膜留茬免耕栽培对旱作玉米田土壤养分、微生物数量及酶活性的影响[J]. 草业学报, 2020, 29(2): 123-133.

ZHANG Jian-jun, DANG Yi, ZHAO Gang, WANG Lei, FAN Ting-lu, LI Shang-zhong, LEI Kang-ning. Effect of no-tillage with film and stubble residues on soil nutrients, microbial populations and enzyme activity in dryland maize fields[J]. Acta Prataculturae Sinica, 2020, 29(2): 123-133.

参考文献

[1] Zhang J J, Fan T L, Zhao G, et al. Effects of no-tillage cultivation reserved plastic films and stubbles on soil moisture temperature and yield of dryland maize. Journal of Nuclear Agricultural Sciences, 2016, 30(11): 2274-2281.
张建军, 樊廷录, 赵刚, 等. 旱地玉米留膜留茬免耕栽培的土壤水热及产量效应. 核农学报, 2016, 30(11): 2274-2281.
[2] Xie J H, Li L L, Zhang R Z, et al. Effect of tillage system on rain-fed maize yield and soil physical characteristics for one film used two years. Journal of Soil and Water Conservation, 2016, 30(3): 184-189, 195.
谢军红, 李玲玲, 张仁陟, 等. 一膜两年覆盖条件下耕作方法对旱作玉米产量及土壤物理性状的影响. 水土保持学报, 2016, 30(3): 184-189, 195.
[3] Zhang J J, Ma M S, Fan T L, et al. Influence of no-tillage plastic and stubble with residues on water consumption characteristics, yield and quality of dryland spring maize. Journal of Agricultural Science and Technology, 2018, 20(12): 107-114.
张建军, 马明生, 樊廷录, 等. 留膜留茬免耕栽培对旱地春玉米耗水特性、产量及品质的影响. 中国农业科技导报, 2018, 20(12): 107-114.
[4] Liu S Z, Feng X, Yu J. Research progress of plants growth-promoting Rhizobacteria and its environmental effects. Hubei Agricultural Sciences, 2009, 48(11): 2882-2887.
刘淑琮, 冯炘, 于洁. 植物根际促生菌的研究进展及其环境作用. 湖北农业科学, 2009, 48(11): 2882-2887.
[5] Cao H, Sun H, Yang H, et al. A review soil enzyme activity and its indication for soil quality. Chinese Journal of Applied and Environmental Biology, 2003, 9(1): 105-109.
曹慧, 孙辉, 杨浩, 等. 土壤酶活性及其对土壤质量的指示研究进展. 应用与环境生物学报, 2003, 9(1): 105-109.
[6] Kathryn P, Yash D, Ram D. Impacts of conservation tillage on soil quality, including soil-borne crop diseases, with a focus semi-arid grain cropping systems. Australasian Plant Pathology, 2013, 42(3): 363-377.
[7] Zhao Y L, Guo H B, Xue Z W, et al. Effects of tillage and straw returning on microorganism quantity, enzyme activities in soils and grain yield. Chinese Journal of Applied Ecology, 2015, 26(6): 1785-1792.
赵亚丽, 郭海斌, 薛志伟, 等. 耕作方式与秸秆还田对土壤微生物数量、酶活性及作物产量的影响. 应用生态学报, 2015, 26(6): 1785-1792.
[8] Zhang R Z, Huang G B, Cai L Q, et al. Dry farmland practice involving multi-conservation tillage measures in the Loess Plateau. Chinese Journal of Eco-Agriculture, 2013, 21(1): 61-69.
张仁陟, 黄高宝, 蔡立群, 等. 几种保护性耕作措施在黄土高原旱作农田的实践. 中国生态农业学报, 2013, 21(1): 61-69.
[9] Luo Z Z, Huang G B, Zhang R Z, et al. Effects of conservation tillage on soil nutrient sand enzyme activities in rain fedarea. Journal of Plant Nutrition and Fertilizers, 2009, 15(5): 1085-1092.
罗珠珠, 黄高宝, 张仁陟, 等. 保护性耕作对旱作农田耕层土壤肥力及酶活性的影响. 植物营养与肥料学报, 2009, 15(5): 1085-1092.
[10] Chen J, Ma Z M, Liu L L, et al. Effect of tillage system on soil organic carbon, microbial biomass and enzyme activities. Journal of Plant Nutrition and Fertilizers, 2016, 22(3): 667-675.
陈娟, 马忠明, 刘莉莉, 等. 不同耕作方式对土壤有机碳、微生物量及酶活性的影响. 植物营养与肥料学报, 2016, 22(3): 667-675.
[11] Doran J W, Sarrantonio M, Liegig M A. Soil health and sustainability. Advances in Agronomy, 1996, 56: 51-54.
[12] Chen S H, Zhu Z L, Liu D H, et al. Influence of straw mulching with no-till on soil nutrients and carbon pool management index. Journal of Plant Nutrition and Fertilizers, 2008, 14(4): 806-809.
陈尚洪, 朱钟麟, 刘定辉, 等. 秸秆还田和免耕对土壤养分及碳库管理指数的影响研究. 植物营养与肥料学报, 2008, 14(4): 806-809.
[13] Li Y J, Wu J Z, Huang M, et al. Effects of different tillage systems on photosynthesis characteristics of flag leaf and water use efficiency in winter wheat. Transactions of the Chinese Society of Agricultural Engineering, 2006, 22(12): 44-48.
李友军, 吴金芝, 黄明, 等. 不同耕作方式对小麦旗叶光合特性和水分利用效率的影响. 农业工程学报, 2006, 22(12): 44-48.
[14] Zhao C, Chen G P, Chai Q, et al. Soil moisture and economic benefits of maize field by 2 years plastic film mulching under different irrigation levels. Agricultural Research in the Arid Areas, 2017, 35(3): 1-6.
赵财, 陈桂平, 柴强, 等. 不同灌水水平下一膜两年覆盖的玉米农田土壤水分和经济效益分析. 干旱地区农业研究, 2017, 35(3): 1-6.
[15] Bao S D. Analysis on soil agricultural chemistry. Beijing: China Agricultural Press, 2000.
鲍士旦. 土壤农化分析. 北京: 中国农业出版社, 2000.
[16] Xu G H, Zheng H Y. Microbial analysis methods manual. Beijing: Agriculture Publishing Press, 1986.
许光辉, 郑洪元. 土壤微生物分析方法手册. 北京: 农业出版社, 1986.
[17] Yan C S. Soil fertility and its research method. Beijing: Science Press, 1988.
严昶升. 土壤肥力研究法. 北京: 科学出版社, 1988.
[18] Zhao L B, Jiang Y. Discussion on measurements of soil phosphates. Chinese Journal of Soil Science, 1986, 7(3): 138-141.
赵兰波, 姜岩. 土壤磷酸酶活性测定方法探讨. 土壤通报, 1986, 17(3): 138-141.
[19] Guan S Y. Soil enzyme and its research method. Beijing: Agricultural Press, 1986: 274-328.
关松荫. 土壤酶及其研究方法. 北京: 农业出版社, 1986: 274-328.
[20] Dolan M S, Clapp C E, Allmaras R R, et al. Soil organic carbon and nitrogen in a Minnesota soil as related to tillage, residue and nitrogen management. Soil & Tillage Research, 2005, 89(2): 221-231.
[21] Liu P C, Qiu H C. Simulated experiment of different ways of straw fertilizing soil. Soil and Fertilizer Sciences in China, 1994, (6): 19-23.
刘鹏程, 丘华昌. 不同方式秸秆还田培肥土壤的模拟试验. 中国土壤与肥料, 1994, (6): 19-23.
[22] Sims A L. Irrigated corn yield and nitrogen accumulation response in a comparison of no-till and conventional till: Tillage and surface-residue variables. Agronomy Journal, 1998, 90(4): 630-637.
[23] Wen S L, Liu J. Effects of the mulch-tillage on the improvement of soil nutrition in Central Gansu. Journal of Gansu Agricultural University, 1996, (1): 27-31.
温随良, 刘军. 陇中旱地少免耕覆盖对提高土壤养分效应的研究. 甘肃农业大学学报, 1996, (1): 27-31.
[24] Needelman B A, Wander M M, Bollero G A, et al. Interaction of tillage and soil texture: Biologically active soil organic matter in illinois. Soil Science Society of America Journal, 1999, 63(5): 1326-1334.
[25] Campbell C A, Selees F, Lafond G P, et al. Adopting zero tillage management: Impact on soil C and N under long-term crop rotations in a thin Black Chernozem. Canadian Journal of Soil Science, 2001, 81(2): 139-148.
[26] Varvel G E, Wilhelm W W. No-tillage increases soil profile carbon and nitrogen under long-term rain-fed cropping systems. Soil and Tillage Research, 2011, 114(1): 28-36.
[27] Hong J P, Xie Y H. Study on soil microbial biomass on condition of different manure. Journal of Shanxi Agricultural University (Natural Science Edition), 1996, 16(1): 19-21.
洪坚平, 谢英荷. 不同施肥条件下土壤微生物生物量的研究. 山西农业大学学报(自然科学版), 1996, 16(1): 19-21.
[28] Li Y, Huang G H, Shi Y. Effect of atmospheric CO₂ enrichment on soil microbes and related factors. Chinese Journal of Applied Ecology, 2003, 14(12): 2321-2325.
李杨, 黄国宏, 史奕. 大气CO₂浓度升高对农田土壤微生物及其相关因素的影响. 应用生态学报, 2003, 14(12): 2321-2325.
[29] Zhang D, Liu H B, Ma Z M, et al. Effect of residual plastic film on soil nutrient contents and microbial characteristics in the farmland. Scientia Agricultura Sinica, 2017, 50(2): 310-319.
张丹, 刘宏斌, 马忠明, 等. 残膜对农田土壤养分含量及微生物特征的影响. 中国农业科学, 2017, 50(2): 310-319.
[30] Yan F, Mcbratney A B, Copeland L. Functional substrate biodiversity of cultivated and uncultivated a horizons of vertisols in NW New South Wales. Geoderma, 2000, 96(40): 321-343.
[31] Chen B, Zhang R Z. Effects of no-tillage and mulch on soil microbial quantity and composition. Journal of Gansu Agricultural University, 2004, 39(6): 634-638.
陈蓓, 张仁陟. 免耕与覆盖对土壤微生物数量及组成的影响. 甘肃农业大学学报, 2004, 39(6): 634-638.
[32] Li C H, Ma B L, Zhang T Q. Soil bulk density effects on microbial populations and enzyme activities during the growth of maize (Zea mays L.) planted in large pots under field exposure. Canadian Journal of Soil Science, 2002, 82(2): 147-154.
[33] Chen Y, Chen B, Zhang J, et al. Effects of no-tillage on soil microbial biomass carbon. Ecology and Environment, 2008, 17(6): 2370-2373.
陈英, 陈蓓, 张军, 等. 免耕覆盖对土壤微生物量碳的影响. 生态环境, 2008, 17(6): 2370-2373.
[34] Yun W, Bin H, Zhong Q. Effects of conservation tillage on soil microbial characters and soil enzyme activities. Journal of Soil and Water Conservation, 2006, 20(4): 120-123.
[35] Liu X M, Li Q, Liang W J, et al. Dynamics of aquic brown soil enzyme activities under no-tillage. Chinese Journal of Applied Ecology, 2006, 17(12): 2347-2351.
刘秀梅, 李琪, 梁文举, 等. 潮棕壤免耕农田土壤酶活性的动态变化. 应用生态学报, 2006, 17(12): 2347-2351.
[36] Yang Z D, Cai L Q, Zhang R Z, et al. Effects of different tillage methods on soil enzyme activities in upland soil. Chinese Journal of Soil Science, 2008, 39(3): 514-517.
杨招弟, 蔡立群, 张仁陟, 等. 不同耕作方式对旱地土壤酶活性的影响. 土壤通报, 2008, 39(3): 514-517.
[37] Zhou R L, Zhang P J, Xu C L. Effect of burning turf on nutrient contents and enzymatic activities of alpine meadow soil and its grey relationship analysis. Acta Pedologica Sinica, 1997, 34(1): 89-96.
周瑞莲, 张普金, 徐长林. 高寒山区火烧土壤对其养分含量和酶活性的影响及灰色关联分析. 土壤学报, 1997, 34(1): 89-96.
[38] Zhou L K, Zhang Z M, Cao C M. On the role of the totality of soil enzyme activities in the evaluation of the level of soil fertility. Acta Pedologica Sinica, 1983, 20(4): 413-418.
周礼恺, 张志明, 曹承绵. 土壤酶活性的总体在评价土壤肥力水平中的作用. 土壤学报, 1983, 20(4): 413-418.
[39] Lin D Y. Soil science. Beijing: China Forestry Press, 2002: 168-202.
林大仪. 土壤学. 北京: 中国林业出版社, 2002: 168-202.