大气沉降与施肥方式对梨园重金属平衡的影响
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摘要
在浙西北平原区和丘陵区分别选择传统施肥、施用化肥和施用商品有机肥等3种不同施肥方式的代表性梨园,进行为期一年的水果生产过程中有机肥、化肥、大气沉降、果实收获和地表径流中重金属流的定点定量观察分析,探讨梨园生态系统中重金属的年平衡值及其影响因素。结果表明,平原区梨园重金属的平衡值普遍高于丘陵区,平原区大气沉降对重金属输入的贡献高于丘陵区。梨园系统中多数重金属积累以施有机肥的最高,Cd主要以化肥方式进入梨园,Zn、Cu、Pb主要通过施有机肥方式进入梨园,而大气沉降对梨园中Zn、Pb、Hg和As积累也有较大的贡献。在丘陵区,传统施肥模式下,除Pb和As稍有积累外,梨园系统中其他重金属元素都呈现下降的趋势;化肥施肥模式下,Pb、Cd和As呈积累趋势,Zn、Cu和Hg呈现降低趋势;而有机肥施肥模式下,所有重金属元素均呈现积累趋势,并以Zn的积累量最高。在平原区,由于大气沉降输入的重金属较多,除传统施肥模式下的Cu和化肥施用模式下的Zn、Cu外,其他重金属元素都呈现积累趋势。
Six typical pear orchards with different fertilization methods(traditional farmyard manure, chemical fertilizer and commercial organic fertilizer) in both plain and hilly regions of northwestern Zhejiang Province are selected to study the flows of Zn, Cu, Pb, Cd, Hg and As loaded by organic manure, chemical fertilizers,atmospheric deposition, pear harvest, and surface runoff in pear production system through one-year field monitoring. The annual mass balance values of the heavy metals in the pear orchard ecological system and their influencing factors are also discussed. The results showed that the balance values of heavy metals of the pear orchard in plain region were higher than those in hilly region. And the input contribution of heavy metals from atmospheric deposition in the plain region was higher than those in the hilly region. Annual accumulation of most of the heavy metals was the highest in the pear orchard applied with organic fertilizer. Cd was mainly from chemical fertilizer, meanwhile Zn, Cu and Pb were mainly from organic fertilizer. The atmospheric deposition also contributed greatly to the accumulation of Zn, Pb, Hg, and As. In the hilly region, for the pear orchard applied with traditional farmyard manure, Pb and As were slightly accumulated, and other heavy metals showed a decreasing trend. For the pear orchard applied with chemical fertilizer, Pb, Cd and As were accumulated,while Zn, Cu and Hg showed a decreasing trend. For the pear orchard applied with commercial organic fertilizer, all of the heavy metals were accumulated with the highest of Zn. Heavy metals in the pear orchards in plain regions, except Cu under conventional fertilization, and Zn and Cu under chemical fertilizer, showed an accumulation trend, due to more input of heavy metals from atmospheric deposition.
Six typical pear orchards with different fertilization methods(traditional farmyard manure, chemical fertilizer and commercial organic fertilizer) in both plain and hilly regions of northwestern Zhejiang Province are selected to study the flows of Zn, Cu, Pb, Cd, Hg and As loaded by organic manure, chemical fertilizers,atmospheric deposition, pear harvest, and surface runoff in pear production system through one-year field monitoring. The annual mass balance values of the heavy metals in the pear orchard ecological system and their influencing factors are also discussed. The results showed that the balance values of heavy metals of the pear orchard in plain region were higher than those in hilly region. And the input contribution of heavy metals from atmospheric deposition in the plain region was higher than those in the hilly region. Annual accumulation of most of the heavy metals was the highest in the pear orchard applied with organic fertilizer. Cd was mainly from chemical fertilizer, meanwhile Zn, Cu and Pb were mainly from organic fertilizer. The atmospheric deposition also contributed greatly to the accumulation of Zn, Pb, Hg, and As. In the hilly region, for the pear orchard applied with traditional farmyard manure, Pb and As were slightly accumulated, and other heavy metals showed a decreasing trend. For the pear orchard applied with chemical fertilizer, Pb, Cd and As were accumulated,while Zn, Cu and Hg showed a decreasing trend. For the pear orchard applied with commercial organic fertilizer, all of the heavy metals were accumulated with the highest of Zn. Heavy metals in the pear orchards in plain regions, except Cu under conventional fertilization, and Zn and Cu under chemical fertilizer, showed an accumulation trend, due to more input of heavy metals from atmospheric deposition.
引文
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[27]刘超.上海市郊大气湿沉降重金属对土壤—叶菜系统的污染效应研究[D].上海:华东师范大学,2016:1-35.
[28]张东明,吕新,王海江,等.工业区周边农田重金属污染评价及来源分析[J].土壤通报,2017,48(3):715-723.
[29]李振国,余光辉,张勇,等.施肥与农田重金属累积的关联性分析——以湖南省为例[J].吉林农业,2017(16):68-69.
[2]杨世琦,刘国强,张爱平,王永生,杨正礼.典型区域果园表层土壤5种重金属累积特征[J].生态学报,2010(22):6201-6207.
[3]章明奎,杨东伟.绍兴平原二种典型农田系统中重金属流及其平衡分析[J].生态与环境学报,2010,19(2):320-324.
[4]丛源,郑萍,陈岳龙,等.北京农田生态系统土壤重金属元素的生态风险评价[J].地质通报,2008,27(5):681-688.
[5]杨忠平,卢文喜,龙玉桥.长春市城区重金属大气干湿沉降特征[J].环境科学研究,2009,22(1):28-33
[6]穆叶赛尔·吐地,吉力力·阿布都外力,姜逢清.天山北坡土壤重金属含量的分布特征及其来源解释[J].中国生态农业学报,2013(7):883-890.
[7]李建国,濮励杰,廖启林,等.无锡市土壤重金属富集的梯度效应与来源差异[J].地理科学,2014(4):496-504.
[8]吕建树,张祖陆,刘洋,等.日照市土壤重金属来源解析及环境风险评价[J].地理学报,2012(7):971-984.
[9]王丽平,孟晓民,左振平,等.浅谈万荣县果园施肥现状中存在的问题及对策[J].农业技术与装备,2011(12):35-36,38.
[10]赵佐平,闫莎,刘芬,等.陕西果园主要分布区氮素投入特点及氮负荷风险分析[J].生态学报,2014(19):5642-5649.
[11]杜瑞英,文典,赵沛华,等.农田土壤重金属污染主要来源识别研究[J].农产品质量与安全,2017(6):61-64.
[12]潘寻.围场县农田土壤重金属污染状况调查与评价[J].河北农业大学学报,2017,40(5):25-31.
[13]师荣光,郑向群,龚琼,等.农产品产地土壤重金属外源污染来源解析及防控策略研究[J].环境监测管理与技术,2017,29(4):9-13.
[14]鲁洪娟,马友华,樊霆,等.有机肥中重金属特征及其控制技术研究进展[J].生态环境学报,2014(12):2022-2030.
[15]潘霞,陈励科,卜元卿,等.畜禽有机肥对典型蔬果地土壤剖面重金属与抗生素分布的影响[J].生态与农村环境学报,2012(5):518-525.
[16]何飞飞,吴小玲,吴爱平,等.果园土壤重金属污染及降污修复技术研究进展[J].作物研究,2012(3):309-313.
[17]刘赫,李双异,汪景宽.长期施用有机肥对棕壤中主要重金属积累的影响[J].生态环境学报,2009(6):2177-2182.
[18]刘子龙.陕西苹果主产区果园土壤重金属污染研究[D].杨凌:西北农林科技大学,2006,1-35.
[19]王飞,赵立欣,沈玉君,等.华北地区畜禽粪便有机肥中重金属含量及溯源分析[J].农业工程学报,2013(19):202-208.
[20]李瑞平,郝英华,李光德,等.泰安市农田土壤重金属污染特征及来源解析[J].农业环境科学学报,2011(10):2012-2017.
[21] Sevel L, Hansen H C B, Raulund-Rasmussen K. Mass balance of cadmium in two contrasting oak forest ecosystems[J]. Journal of Environmental Quality,2009,38(1):93-102.
[22]徐勇贤,王洪杰,黄标,等.长三角工业型城乡交错区蔬菜生产系统重金属平衡及健康风险[J].土壤,2009,41(4):548-555.
[23]李春芳,王菲,曹文涛,等.龙口市污水灌溉区农田重金属来源、空间分布及污染评价[J].环境科学,2017,38(3):1018-1027.
[24] Spark D L. Methods of Soil Analysis, Part 3:Chemical Methods[M]. Madison:SSSA and ASA,1996:703-919.
[25]鲁如坤.土壤农化分析方法[M].北京:中国农业科技出版社,2000:15-123.
[26]陈志凡,范礼东,陈云增,等.城乡交错区农田土壤重金属总量及形态空间分布特征与源分析——以河南省某市东郊城乡交错区为例[J].环境科学学报,2016,36(4):1317-1327.
[27]刘超.上海市郊大气湿沉降重金属对土壤—叶菜系统的污染效应研究[D].上海:华东师范大学,2016:1-35.
[28]张东明,吕新,王海江,等.工业区周边农田重金属污染评价及来源分析[J].土壤通报,2017,48(3):715-723.
[29]李振国,余光辉,张勇,等.施肥与农田重金属累积的关联性分析——以湖南省为例[J].吉林农业,2017(16):68-69.
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