秸秆和生物质炭对苹果园土壤容重、阳离子 交换量和氮素利用的影响

doi:10.3864/j.issn.0578-1752.2014.02.016

摘要/Abstract

摘要： 【目的】中国苹果园土壤有机碳含量较低，氮肥施用量偏高。本研究为苹果生产上合理应用秸秆和生物质炭来提高土壤缓冲性能和氮肥利用效率提供依据。【方法】以两年生富士/平邑甜茶为试材，采用15N标记示踪技术，研究添加秸秆和生物质炭对土壤容重、阳离子交换量、植株生长及氮素转化（树体吸收、氨挥发、N2O排放和土壤残留）的影响。试验共设4个处理：对照（CK）、单施氮肥（N）、施用氮肥并添加生物质炭（N+B）和施用氮肥并添加秸秆(N+S)。【结果】不同处理的土壤容重在0—5 cm和5—10 cm两个土层中的变化趋势一致。CK与N处理间差异不显著，但均显著高于N+B和N+S处理；两个添加外源碳的处理间，N+B处理的土壤容重显著低于N+S处理。与N处理相比，N+S和N+B处理的0—5 cm和5—10 cm两个土层的容重分别降低了0.06、0.09 g•cm-3和0.07、0.11 g•cm-3。与CK（18.32 cmol•kg-1）和N（19.61 cmol•kg-1）处理相比，N+S（22.27 cmol•kg-1）和N+B处理（25.35 cmol•kg-1）显著提高了0—10 cm土层土壤阳离子交换量，并且以N+B处理效果较好。3个施氮处理间植株总干重、15N积累量和15N利用率均以N+B处理最高，N+S处理次之，N处理最低。与CK相比，3个施氮处理（N、N+S和N+B处理）的氨挥发量均显著增加。与N处理相比，添加外源碳的两个处理（N+S和N+B处理）显著减少了氨挥发损失量，以N+B处理减少幅度最大。与CK相比，3个施N处理（N、N+S和N+B处理）的N2O排放量均显著增加，以N+B处理最高，其次为N+S处理，N处理最低，可见添加外源碳的两个处理的N2O排放量均有所增加，但3个施氮处理间差异不显著。去掉CK本底值后，N、N+S和N+B处理的氮素总气态损失量（氨挥发+N2O排放）占施氮量的比例分别为6.54%、4.33%和3.04%。可见，添加秸秆和生物质炭显著降低了氮素气态损失，以N+B处理效果较好。耕层土壤（0—50 cm）的15N残留量以N+B处理最高，N+S处理次之，N处理最低；而深层土壤（50—100 cm）则以N处理最高，N+S处理次之，N+B处理最低。3个施氮处理间，N回收率（树体吸收+土壤残留）以N+B处理最高，为42.26%，其次为N+S处理（37.22%），N处理最低（31.54%）；N损失率以N处理最高，为68.46%。其次为N+S处理（62.78%），N+B处理最低（57.74%）。【结论】添加秸秆和生物质炭显著降低了土壤容重，提高了土壤阳离子交换量，促进了苹果植株生长和对肥料氮的吸收，增加了土壤对氮的固定，减少了氮肥的气态损失，提高了氮肥利用率，其中以添加生物质炭的效果较好。

关键词: 苹果 , 秸秆 , 生物质炭 , 土壤容重 , 阳离子交换量 , 氮素吸收和损失

Abstract: 【Objective】The soil organic carbon content is low but the nitrogen fertilizer application rate is high in apple orchards in China. This study was conducted in order to provide a theoretical basis for the appropriate application of straw and biochar in apple production. 【Method】Two-year-old ‘Fuji’ apple trees (Malus domestica Borkh. cv Red Fuji/Malus hupehensis) trees were used to study the effect of straw and biochar on soil bulk density, cation exchange capacity (CEC), tree growth, and 15N transformation (tree uptake, ammonia volatilization, N2O emission, and soil residual) using 15N trace technique. There were four treatments: CK (control), N (only nitrogen fertilizer), N + B (nitrogen fertilizer + biochar) and N + S (nitrogen fertilizer + straw). 【Result】 The variation trend of soil bulk density in 0-5 and 5-10 cm soil layers was consistent in the four different treatments. There was no significant difference between CK and N treatment, but both were significantly higher than those in N + B and N + S treatments. For the two added exogenous carbon treatments, soil bulk density in N + B treatment was significantly lower than that of N + S treatment. Compared with the N treatment, soil bulk density in 0-5 and 5-10 cm soil layers in N + S and N + B treatments decreased by 0.06, 0.09 and 0.07, 0.11 g•cm-3, respectively. Compared with CK (18.32 cmol•kg-1) and N treatment (19.61 cmol•kg-1), the CEC of 0-10 cm soil layer increased significantly in N + S treatment (22.27 cmol•kg-1) and N + B treatment (25.35 cmol•kg-1). The highest total weight of apple trees, 15N uptake amount and 15N utilization efficiency existed in N + B treatment, followed by N + S treatment, and the lowest of those values were found in N treatment. Compared with CK, the amounts of ammonia volatilization significantly increased in the three N application treatments (N, N + S and N + B). Compared with N treatment, N + S and N + B treatments significantly reduced the N loss through ammonia volatilization, especially in N + B treatment. Compared with CK, the amounts of N2O emission were significantly increased in the three N application treatments (N, N + S and N + B), and the highest was found in N + B treatment, followed by N + S treatment, and N treatment was the lowest. So, addition of exogenous carbon could increase N2O emission rate, but no significant difference was found among the three nitrogen application treatments. When the CK background value was removed, total N gaseous losses (ammonia volatilization + N2O emissions) in N, N + S and N + B treatments accounted for the proportion of N application rate were 6.54%, 4.33% and 3.04%, respectively. The highest 15N residual rate in 0-50 cm soil layer was found in N + B treatment, followed by N + S and N treatment; while the highest 15N residual rate was found in N treatment, followed by N + S and N + B treatment in 50-100 cm. The highest N recovery rate was found in N + B treatment (42.26%), followed by N + S treatment (37.22%), and N treatment (31.54%) was the lowest; so the highest N loss rate appeared in N treatment (68.46%), followed by N + S treatment (62.78%) and N + B treatment (57.74%). 【Conclusion】Application of straw and biochar into apple orchard soil could decrease the soil bulk density, increase the soil cation exchange capacity, improve plant growth, promote N uptake by plant, increase the N fixed by soil and decrease N gaseous loss. The result will get better when application of biochar.

Key words: apple , straw , biochar , soil bulk density , CEC , N absorption and loss

葛顺峰, 彭玲, 任饴华, 姜远茂. 秸秆和生物质炭对苹果园土壤容重、阳离子交换量和氮素利用的影响[J]. 中国农业科学, 2014, 47(2): 366-373.

GE Shun-Feng, PENG Ling, REN Yi-Hua, JIANG Yuan-Mao. Effect of Straw and Biochar on Soil Bulk Density, Cation Exchange Capacity and Nitrogen Absorption in Apple Orchard Soil[J]. Scientia Agricultura Sinica, 2014, 47(2): 366-373.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2014.02.016

https://www.chinaagrisci.com/CN/Y2014/V47/I2/366

参考文献

[1]彭福田, 姜远茂. 不同产量水平苹果园氮磷钾营养特点研究. 中国农业科学, 2006, 39(2): 361-367.

Peng F T, Jiang Y M. Characteristics of N, P, and K Nutrition in different yield level apple orchards. Scientia Agricultura Sinica, 2006, 39(2): 361-367. (in Chinese)

[2]葛顺峰, 姜远茂, 魏绍冲, 房祥吉. 不同供氮水平下幼龄苹果园氮素去向初探. 植物营养与肥料学报, 2011, 17 (4): 950-956.

Ge S F, Jiang Y M, Wei S C, Fang X J. Nitrogen balance under different nitrogen application rates in young apple orchards. Plant Nutrition and Fertilizer Science, 2011, 17 (4): 950-956. (in Chinese)

[3]Laura S M, Vallejo A, Dick J, Skiba U M. The influence of soluble carbon and fertilizer nitrogen on nitric oxide and nitrous oxide emissions from two contrasting agricultural soils. Soil Biology and Biochemistry, 2008, 40(1): 142-151.

[4]Schipper L A, Sparling G P. Accumulation of soil organic C and change in C:N ratio after establishment of pastures on reverted scrubland in New Zealand. Biogeochemistry, 2011, 104: 49-58.

[5]Sentile R, Vanlauwe B, Chivenge P, Six J. Interactive effects from combining fertilizer and organic residue inputs on nitrogen transformations. Soil Biology and Biochemistry, 2008, 40: 2375-2384.

[6]Murray P J, Hatch D J, Dixon E R, Stevens R J, Laughlin R J, Jarvis S C. Denitrification potential in a grassland sub soil effect of carbon substrates. Soil Biology and Biochemistry, 2004, 36: 545-547.

[7]Eagle A J, Bird J A, Horwath W R, Linquist B A, Brouder S M, Hill J E, Kessel C V. Rice yield and nitrogen efficiency under alternative straw management practices. Agronomy Journal, 2000, 92: 1096-1103.

[8]徐国伟, 段骅, 王志琴, 刘立军, 杨建昌. 麦秆还田对土壤理化性质及酶活性的影响. 中国农业科学, 2009, 42(3): 934-942.

Xu G W, Duan Y, Wang Z Q, Liu L J, Yang J C. Effect of wheat-residue application on physical and chemical characters and enzymatic activities in soil. Scientia Agricultura Sinica, 2009, 42(3): 934-942. (in Chinese)

[9]Kimetu J M, Lehmann J. Stability and stabilisation of biochar and green manure in soil with different organic carbon contents. Australian Journal of Soil Research, 2010, 48(7): 577-585.

[10]Atkinson C, Fitzgerald J, Hipps N. Potential mechanisms for achieving agricultural benefits from biochar application to temperate soils: A review. Plant and Soil, 2010, 337: 1-18.

[11]Laird D A, Fleming P, Davis D D, Horton R, Wang B, Karlen D L. Impact of biochar amendments on the quality of a typical Midwestern agricultural soil. Geoderma, 2010, 158: 443-449

[12]董文旭, 胡春胜, 张玉铭. 华北农田土壤氨挥发原位测定研究. 中国生态农业学报, 2006, 12(3): 46-48.

Dong W X, Hu C S, Zhang Y M. In situ determination of ammonia volatilization in field of North China. Chinese Journal of Eco-Agriculture, 2006, 114(13): 46-48. (in Chinese)

[13]林成谷. 土壤学. 北京: 农业出版社, 1998.

Lin C G. Soil. Beijing: China Agriculture Press, 1998. (in Chinese)

[14]Chen Y, Shinogi Y, Taira M. Influence of biochar use on sugarcane growth, soil parameters, and groundwater quality. Australian Journal of Soil Research, 2010, 48: 526-530.

[15]Brodowski S, John B, Flessa H, Amelung W. Aggregate-occluded black carbon in soil. European Journal of Soil Science, 2006, 57(4): 539-546.

[16]Glaser B, Lehmann J, Zech W. Ameliorating physical and chemical properties of highly weathered soils in the tropics with charcoal: A review. Biology and Fertility of Soils, 2002, 35(4): 219-230.

[17]Liang B, Lehmann J, Solomon D, Kinyangia J, Grossmana J, O'Neilla B, Skjemstadb J O, Thiesa J, Luizãoc F J, Petersend J, Nevese E G. Black carbon increases cation exchange capacity in soils. Soil Science Society of America Journal, 2006, 70(5): 1719-1730.

[18]葛顺峰, 姜远茂, 彭福田, 房祥吉, 王海宁, 东明学, 刘建才. 春季有机肥和化肥配施对苹果园土壤氨挥发的影响. 水土保持学报, 2010, 24(5): 199-203.

Ge S F, Jiang Y M, Peng F T, Fang X J, Wang H N, Dong M X, Liu J C. Effect of chemical fertilizers application combined with organic manure on ammonia volatilization in spring in apple orchard. Journal of Soil and Water Conservation, 2010, 24(5): 199-203. (in Chinese)

[19]葛顺峰, 周乐, 门永阁, 李红娜, 魏绍冲, 姜远茂. 添加不同碳源对苹果园土壤氮磷淋溶损失的影响. 水土保持学报, 2013, 27(2): 31-35.

Ge S F, Zhou L, Men Y G, Li H N, Wei S C, Jiang Y M. Effect of carbon application on nitrogen and phosphorus leaching in apple orchard soil. Journal of Soil and Water Conservation, 2013, 27(2): 31-35. (in Chinese)

[20]Steiner C, Glaser B, Teixeira W G, Lehmann J, Blum W E H, Zech W. Nitrogen retention and plant uptake on a highly weathered central Amazonian Ferrasol amended with compost and charcoal. Journal of Plant Nutrition Soil Science, 2008, 171(6): 893-899.

[21]姚槐应, 何振立, 黄昌勇. 提高氮肥利用效率的微生物量机制探讨. 农业环境保护, 1999, 18(2): 54-56.

Yao H Y, He Z L, Huang C Y. Effect of nitrogen fertilizer in combination with organic carbon on nitrogen availability. Agro-Environmental Protection, 1999, 18(2): 54-56. (in Chinese)

[22]胡诚, 曹志平, 罗艳蕊, 马永良. 长期施用生物有机肥对土壤肥力及微生物生物量碳的影响. 中国生态农业学报, 2007, 15(3): 48-51.

Hu C, Cao Z P, Luo Y R, Ma Y L. Effect of long-term application of microorganismic compost or vermicompost on soil fertility and microbial biomass carbon. Chinese Journal of Eco-Agriculture, 2007, 15(3): 48-51. (in Chinese)

[23]葛顺峰, 姜远茂, 陈倩, 周恩达, 王富林, 房祥吉. 土壤有机质含量对平邑甜茶生长及氮素吸收和损失的影响. 水土保持学报, 2011, 26(1): 81-84.

Ge S F, Jiang Y M, Chen Q, Zhou E D, Wang F L, Fang X J. Effect of soil organic matter content on growth and 15N absorption, utilization and loss of Malus hupehensis. Journal of Soil and Water Conservation, 2011, 26(1): 81-84. (in Chinese)

[24]刘新宇, 巨晓棠, 张丽娟, 李鑫, 袁丽金, 刘楠. 不同施氮水平对冬小麦季化肥氮去向及土壤氮素平衡的影响. 植物营养与肥料学报, 2010, 16(2): 296-303.

Liu Y X, Ju X T, Zhang L J, Li X, Yuan L J, Liu N. Effects of different N rates on fate of N fertilizer and balance of soil N of winter wheat. Plant Nutrition and Fertilizer Science, 2010, 16(2): 296-303. (in Chinese)

[25]郭天才, 宋晓, 冯伟, 马冬云, 谢迎新, 王永华. 高产麦田氮素利用、氮平衡及适宜施氮量. 作物学报, 2008, 34(5): 886- 892.

Guo T C, Song X, Feng W, Ma D Y, Xie Y X, Wang Y H. Utilization and balance of nitrogen and proper application amount of nitrogen fertilizer in w inter wheat in high yielding regions. Acta Agronomica Sinica, 2008, 34(5): 886-892. (in Chinese)

[26]朱兆良. 氮素管理与粮食生产和环境. 土壤学报, 2002, 39(增刊): 3-11.

Zhu Z L. Nitrogen management in relation to food production and environment in china. Acta Pedologica Sinica, 2002, 39(Suppl.): 3-11. (in Chinese)