首页 > 过刊浏览>2023年第60卷第3期 >868-880. DOI:10.11766/trxb202106090303
PDF HTML阅读 XML下载 导出引用 引用提醒
紫云英翻压还田对稻田土壤团聚体组成及其碳氮的影响
作者:
中图分类号:

S158.5

基金项目:

国家自然科学基金项目(41807106)和现代农业产业技术体系建设专项资金(CARS-22)资助


Continuous Multi-year Application of Chinese Milk Vetch in Paddy Soil and Its Effect on Soil Aggregates Distribution and Their Carbon and Nitrogen Content
Author:
Fund Project:

Supported by the National Natural Science Foundation of China (No. 41807106) and the Earmarked Fund for Modern Agro-industry Technology Research System-Green Manure (No. CARS-22)

  • 摘要
    • | |
  • 访问统计
    • |
  • 参考文献 [37]
    • |
  • 相似文献 [20]
    • | | |
  • 文章评论
    摘要:

    紫云英翻压还田是南方传统稻田土壤培肥增产的主要措施。依托连续12年田间定位试验,通过设置CK(不施化肥,紫云英不还田)、单施化肥(GM0)和4个梯度的紫云英翻压量(GM1-4)处理,分析连续多年紫云英翻压还田对稻田土壤团聚体组分、团聚体中碳氮含量和储量,并通过傅里叶红外光谱测定各粒级有机官能团类型及相对含量,探讨连续多年紫云英翻压还田对土壤团聚体组分及其碳氮分布的影响。结果表明,在该土壤中粒级>2 mm土壤团聚体含量最高,占总量的61.12%~68.53%,其次是2~0.25 mm粒级团聚体。紫云英翻压还田较单施化肥处理提高了>2 mm粒级团聚体所占百分比(5.93%~9.91%)。紫云英翻压还田提高了粒级>0.053 mm团聚体中有机碳含量和各个粒级中全氮含量,其中粒级>0.25 mm团聚体的碳氮含量与紫云英翻压量之间呈现出显著正相关关系。紫云英翻压还田分别显著提高了19.42%~37.09%有机碳和22.31%~40.13%氮的总储量,其中粒级>2 mm团聚体中碳氮储量随着紫云英翻压量的增加而增加。>2 mm粒级团聚体中碳氮的分布也随着紫云英的翻压还田而增加。通过傅里叶红外光谱认为土壤各粒级团聚体中脂肪族有机碳和芳香族有机碳以及N-H官能团含量也随着紫云英翻压还田而增加,其中N-H官能团含量与紫云英翻压量之间呈现出显著的正相关关系。紫云英翻压还田同时提高了各团聚体中1 630/2 850+2 940和1 720/2 850+2 940相对比值,其中>2 mm和2~0.25 mm粒级团聚体中1 630/2 850+2 940相对强度比值与紫云英翻压量之间均呈显著性相关关系。综上,紫云英翻压还田不仅有利于改善稻田土壤团聚体组分,增加有机碳和全氮在土壤团聚体中的储存,还提高了团聚体有机碳的活性和稳定性,从而有助于提升稻田土壤肥力。

    Abstract:

    【Objective】The application of Chinese milk vetch to paddy soil is an effective practice to improve soil fertility and maintain high and stable yields in South China. The soil aggregates distributions and their carbon and nitrogen content may be influenced by the continuous multi-year application of Chinese milk vetch.【Method】We investigated the effects of 12 years of Chinese milk vetch returned to soil on soil aggregate size distribution and aggregate-associated carbon and nitrogen by setting with six treatments including CK (no fertilizers and no Chinese milk vetch applied), GM0 (fertilizer only) and four gradients of Chinese milk vetch applied (GM1-4). The aggregate size distribution and the content and storage of organic carbon and nitrogen in the soil aggregate were analyzed. Also the types and relative intensity of organic functional groups in different size classes were determined using Fourier Transform Infrared spectrometer (FTIR).【Result】The results showed that the >2 mm soil aggregate was dominant (61.12%~68.53%)and followed by the 2~0.25 mm fraction. The application of Chinese milk vetch increased the percentage of the soil aggregate size (>2 mm) by 5.93%~9.91%. Also, the contents of organic carbon and total nitrogen in the >0.053 mm aggregates increased with the application rate of the treatment. There was a significant positive correlation between the contents of organic carbon and total nitrogen and the application rates of Chinese milk vetch. Interestingly, the application of Chinese milk vetch increased the total storage of organic carbon and nitrogen by 19.42%~37.09% and 22.31%~40.13%, respectively. Moreover, the distribution of organic carbon and nitrogen in >2 mm soil aggregate was also increased after the treatment. FTIR spectroscopic analysis revealed that the relative contents of aliphatic and aromatic organic carbons in soil aggregates were increased after treatment, and there was a significant positive correlation between the N-H functional groups and the application rate of Chinese milk vetch. In addition, the relative intensities of 1 630/2 850+2 940 and 1 720/2 850+2 940 in different soil aggregates were increased. There was a significant positive correlation between the values of the relative intensity of 1 630/2 850+2 940 in both aggregate sizes of >2 mm and 2~0.25mm and the application of Chinese milk vetch.【Conclusion】The application of Chinese milk vetch to paddy soil improved the distribution of soil aggregates, increased the activity and stability of organic carbon, and enhanced the organic carbon and nitrogen storage in soil aggregates. These positive impacts of Chinese milk vetch played an important role in enhancing paddy soil fertility.

    参考文献
    [1] Gao J S,Huang J,Yang Z C,et al. Improving organic matter content and nitrogen supply stability of double cropping rice field through co-incorporation of green manure and rice straw[J]. Journal of Plant Nutrition and Fertilizers,2020,26(3):472-480.[高菊生,黄晶,杨志长,等. 绿肥和稻草联合还田提高土壤有机质含量并稳定氮素供应[J]. 植物营养与肥料学报,2020,26(3):472-480.]
    [2] Cao W D,Bao X G,Xu C X,et al. Reviews and prospects on science and technology of green manure in China[J]. Journal of Plant Nutrition and Fertilizer,2017,23(6):1450-1461.[曹卫东,包兴国,徐昌旭,等. 中国绿肥科研60年回顾与未来展望[J]. 植物营养与肥料学报,2017,23(6):1450-1461.]
    [3] Liu Y Y,Bu R Y,Tang S,et al. Effect of continuous straw-Chinese milk vetch synergistic return to the field on yield,nutrient accumulation and soil fertility of double cropping rice[J]. Journal of Plant Nutrition and Fertilizers,2020,26(6):1008-1016.[刘颖颖,卜容燕,唐杉,等. 连续秸秆-紫云英协同还田对双季稻产量、养分积累及土壤肥力的影响[J]. 植物营养与肥料学报,2020,26(6):1008-1016.]
    [4] Huang R,Lan M L,Liu J,et al. Soil aggregate and organic carbon distribution at dry land soil and paddy soil:The role of different straws returning[J]. Environmental Science and Pollution Research,2017,24(36):27942-27952.
    [5] Wang H,Tang S,Han S,et al. Rational utilization of Chinese milk vetch improves soil fertility,rice production,and fertilizer use efficiency in double-rice cropping system in East China[J]. Soil Science and Plant Nutrition,2021,67(2):171-179.
    [6] Gao S J,Zhou G P,Cao W D. Effects of milk vetch(Astragalus sinicus)as winter green manure on rice yield and rate of fertilizer application in rice paddies in South China[J]. Journal of Plant Nutrition and Fertilizers,2020,26(12):2115-2126.[高嵩涓,周国朋,曹卫东. 南方稻田紫云英作冬绿肥的增产节肥效应与机制[J]. 植物营养与肥料学报,2020,26(12):2115-2126.]
    [7] Zhou F L,Li F,Huang Y N,et al. Effects of adding Chinese milk vetch on soil aggregates composition and organic carbon distribution[J]. Soils,2020,52(4):781-788.[周方亮,李峰,黄雅楠,等. 紫云英添加对土壤团聚体组成及有机碳分布的影响[J]. 土壤,2020,52(4):781-788.]
    [8] Chen E F,Guan L Z,Wang J K,et al. Compositional proportion of soil characteristic microaggregates and soil fertility evaluation[J]. Acta Pedologica Sinica,2001,38(1):49-53.[陈恩凤,关连珠,汪景宽,等. 土壤特征微团聚体的组成比例与肥力评价[J]. 土壤学报,2001,38(1):49-53.]
    [9] Nie X,Lu Y H,Liao Y L,et al. Effects of the incorporation of various amounts of Chinese milk vetch and reducing chemical fertilizer on water-stable aggregates and yield in double cropping rice system[J]. Acta Agriculturae Boreali-Sinica,2020,35(6):155-164.[聂鑫,鲁艳红,廖育林,等. 化肥减施下紫云英不同翻压量对水稳性团聚体及双季稻产量的影响[J]. 华北农学报,2020,35(6):155-164.]
    [10] Yu Q G,Yang Y,Zou P,et al. Effect of organic materials application on soil aggregate and soil organic carbon in rice fields[J]. Journal of Soil and Water Conservation,2017,31(6):170-175.[俞巧钢,杨艳,邹平,等. 有机物料对稻田土壤团聚体及有机碳分布的影响[J]. 水土保持学报,2017,31(6):170-175.]
    [11] Liu C Z,Liu X F,Li B Y,et al. Effects of applying Chinese milk vetch with different amounts of chemical fertilizer on soil nutrients,aggregation and rice yield[J]. Chinese Journal of Soil Science,2013,44(2):409-413.[刘春增,刘小粉,李本银,等. 紫云英配施不同用量化肥对土壤养分、团聚性及水稻产量的影响[J]. 土壤通报,2013,44(2):409-413.]
    [12] He C M,Zhong S J,Li Q H,et al. Effects of planting and overturning milk vetch on properties of surface soil structure and content of organic carbon[J]. Acta Agriculturae Jiangxi,2014,26(12):32-34,37.[何春梅,钟少杰,李清华,等. 种植翻压紫云英对耕层土壤结构性能及有机碳含量的影响[J]. 江西农业学报,2014,26(12):32-34,37.]
    [13] Chang D N. Characteristics of soil dissolved organic matter in main green manure plantation systems in China[D]. Beijing:Chinese Academy of Agricultural Sciences,2015.[常单娜. 我国主要绿肥种植体系中土壤可溶性有机物特性研究[D]. 北京:中国农业科学院,2015.]
    [14] Song J,Huang J,Gao J S,et al. Effects of green manure planted in winter and straw returning on soil aggregates and organic matter functional groups in double cropping rice area[J]. Chinese Journal of Applied Ecology,2021,32(2):564-570.[宋佳,黄晶,高菊生,等. 冬种绿肥和秸秆还田对双季稻区土壤团聚体和有机质官能团的影响[J]. 应用生态学报,2021,32(2):564-570.]
    [15] Bao S D. Soil and agricultural chemistry analysis[M]. Beijing:China Agriculture Press,2000.[鲍士旦. 土壤农化分析[M]. 北京:中国农业出版社,2000.]
    [16] Xue B,Huang L,Lu J W,et al. Effects of continuous straw returning and No-tillage on soil aggregates and organic carbon[J]. Journal of Soil and Water Conservation,2018,32(1):182-189.[薛斌,黄丽,鲁剑巍,等. 连续秸秆还田和免耕对土壤团聚体及有机碳的影响[J]. 水土保持学报,2018,32(1):182-189.]
    [17] Eynard A,Schumacher T E,Lindstrom M J,et al. Effects of agricultural management systems on soil organic carbon in aggregates of Ustolls and Usterts[J]. Soil and Tillage Research,2005,81(2):253-263.
    [18] Wu J G,Wang M H,Wan Z M,et al. Chemical composition and structure of humic acid from composted corn stalk residue[J]. Acta Pedologica Sinica,2006,43(3):443-451.[吴景贵,王明辉,万忠梅,等. 玉米秸秆腐解过程中形成胡敏酸的组成和结构研究[J]. 土壤学报,2006,43(3):443-451.]
    [19] Guan S,Dou S,Ma L N,et al. Effects of long-term application of horse manure on quantity and quality of humic substance in aggregates of dark brown soil[J]. Acta Pedologica Sinica,2017,54(5):1195-1205.[关松,窦森,马丽娜,等. 长施马粪对暗棕壤团聚体腐殖质数量和质量的影响[J]. 土壤学报,2017,54(5):1195-1205.]
    [20] He M,Wang Y C,Wang L G,et al. Using DNDC model to simulate black soil organic carbon dynamics as well as its coordinate relationship with crop yield[J]. Journal of Plant Nutrition and Fertilizer,2017,23(1):9-19.[贺美,王迎春,王立刚,等. 应用DNDC模型分析东北黑土有机碳演变规律及其与作物产量之间的协同关系[J]. 植物营养与肥料学报,2017,23(1):9-19.]
    [21] Sodhi G P S,Beri V,Benbi D K. Using carbon management index to assess the impact of compost application on changes in soil carbon after ten years of rice-wheat cropping[J]. Communications in Soil Science and Plant Analysis,2009,40(21/22):3491-3502.
    [22] Meng H Q,Lü J L,Xu M G,et al. Alkalinity of organic manure and its mechanism for mitigating soil acidification[J]. Plant Nutrition and Fertilizer Science,2012,18(5):1153-1160.[孟红旗,吕家珑,徐明岗,等. 有机肥的碱度及其减缓土壤酸化的机制[J]. 植物营养与肥料学报,2012,18(5):1153-1160.]
    [23] Bhattacharyya R,Prakash V,Kundu S,et al. Long term effects of fertilization on carbon and nitrogen sequestration and aggregate associated carbon and nitrogen in the Indian sub-Himalayas[J]. Nutrient Cycling in Agroecosystems,2010,86(1):1-16.
    [24] Elliott E T. Aggregate structure and carbon,nitrogen,and phosphorus in native and cultivated soils[J]. Soil Science Society of America Journal,1986,50(3):627-633.
    [25] Kiem R,Knicker H,Körschens M,et al. Refractory organic carbon in C-depleted arable soils,as studied by 13C NMR spectroscopy and carbohydrate analysis[J]. Organic Geochemistry,2000,31(7/8):655-668.
    [26] Yin B K,Zhou L Q,Yin B,et al. Effects of organic amendments on rice(Oryza sativa L.)growth and uptake of heavy metals in contaminated soil[J]. Journal of Soils and Sediments,2016,16(2):537-546.
    [27] An Y Y,Ma K,Wang M G,et al. Effect of maize straw returning to field on soil aggregates and their carbon and nitrogen distributions[J]. Acta Agriculturae Boreali-occidentalis Sinica,2020,29(5):766-775.[安嫄嫄,马琨,王明国,等. 玉米秸秆还田对土壤团聚体组成及其碳氮分布的影响[J]. 西北农业学报,2020,29(5):766-775.]
    [28] Gao S J,Gao J S,Cao W D,et al. Effects of long-term green manure application on the content and structure of dissolved organic matter in red paddy soil[J]. Journal of Integrative Agriculture,2018,17(8):1852-1860.
    [29] Dhillon G S,Gillespie A,Peak D,et al. Spectroscopic investigation of soil organic matter composition for shelterbelt agroforestry systems[J]. Geoderma,2017,298:1-13.
    [30] Barbera V,Poma I,Gristina L,et al. Long-term cropping systems and tillage management effects on soil organic carbon stock and steady state level of C sequestration rates in a semiarid environment[J]. Land Degradation & Development,2012,23(1):82-91.
    [31] Chaney K,Swift R S. Studies on aggregate stability:II. The effect of humic substances on the stability of reformed soil aggregates[J]. Journal of Soil Science,1986,37(2):337-343.
    [32] Yang J,Guo W Q,Yang W H,et al. Migration and risk of loss of soluble organic nitrogen in paddy soil after incorporation of Chinese milk vetch[J]. Acta Pedologica Sinica,2022,29(3):DOI:10.11766/trxb202009100469.[杨静,郭文圻,杨文浩,等. 紫云英翻压后稻田土壤可溶性有机氮迁移特性与损失风险[J]. 土壤学报,2022,29(3):DOI:10.11766/trxb202009100469.]
    [33] Gao S J,Zhou G P,Cao W D. Impacts of plantation of winter green manure crops on soil nitrification in paddy soil[J]. Acta Pedologica Sinica,2022,59(1):263-273.[高嵩涓,周国朋,曹卫东. 冬种绿肥对水稻土硝化作用的影响[J]. 土壤学报,2022,59(1):263-273.]
    [34] Liu C Z,Zhang C L,Li B Y,et al. Effects of Astragalus sinicus combined with chemical fertilizer on nitrogen absorption and utilization of rice and nitrogen distribution and residue of Astragalus sinicus in rice-soil system[J]. Chinese Journal of Applied Ecology,2021,32(5):1791-1798.[刘春增,张成兰,李本银,等. 紫云英配施化肥对水稻氮素吸收利用和紫云英氮在水稻-土壤体系分配、残留的影响[J]. 应用生态学报,2021,32(5):1791-1798.]
    [35] Zhang Q,Zhang A H,Yao D J,et al. Distribution and sequestration of nitrogen in soil aggregates under continuous cultivation of green manure crops[J]. Chinese Journal of Soil Science,2019,50(3):577-584.[张钦,张爱华,姚单君,等. 连续种植不同绿肥作物的耕层土壤团聚体中氮分布及其固持特征[J]. 土壤通报,2019,50(3):577-584.]
    [36] An W L,Gao D Z,Pan T,et al. Effect of rice straw returning on paddy soil water-stable aggregate distribution and stability in the paddy field of Fuzhou plain[J]. Acta Scientiae Circumstantiae,2016,36(5):1833-1840.[安婉丽,高灯州,潘婷,等. 水稻秸秆还田对福州平原稻田土壤水稳性团聚体分布及稳定性影响[J]. 环境科学学报,2016,36(5):1833-1840.]
    [37] Liu Z,Sun Z H,Zhang R Q. Effects of application of rice straw on distribution and stability of aggregates and organic carbon in fluvo-aquic[J]. Southwest China Journal of Agricultural Sciences,2018,31(6):1246-1252.[刘哲,孙增慧,张瑞庆. 秸秆添加对潮土团聚体及有机碳分布和稳定性的影响[J]. 西南农业学报,2018,31(6):1246-1252.]
    引证文献
    网友评论
    网友评论
    分享到微博
    发 布
引用本文

王慧,韩上,唐杉,程文龙,卜容燕,李敏,武际,王允青,曹卫东.紫云英翻压还田对稻田土壤团聚体组成及其碳氮的影响[J].土壤学报,2023,60(3):868-880. DOI:10.11766/trxb202106090303 WANG Hui, HAN Shang, TANG Shan, CHENG Wenlong, BU Rongyan, LI Min, WU Ji, WANG Yunqing, CAO Weidong. Continuous Multi-year Application of Chinese Milk Vetch in Paddy Soil and Its Effect on Soil Aggregates Distribution and Their Carbon and Nitrogen Content[J]. Acta Pedologica Sinica,2023,60(3):868-880.

复制
分享
文章指标
  • 点击次数:581
  • 下载次数: 1818
  • HTML阅读次数: 1140
  • 引用次数: 0
历史
  • 收稿日期:2021-06-09
  • 最后修改日期:2022-01-08
  • 录用日期:2022-03-30
  • 在线发布日期: 2022-04-06
  • 出版日期: 2023-05-28
文章二维码
今日访问量:483 您是第8264592 位访问者
通讯地址:江苏省南京市江宁区麒麟街道创优路298号 邮政编码:211135 电话:025-86881237
网址:http://pedologica.issas.ac.cn/ E-mail:actapedo@issas.ac.cn
版权所有:《土壤学报》编辑部 技术支持:北京勤云科技发展有限公司 ICP:05004320号-1