氮排放量评估及降氮潜力研究——以浙江省为例

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摘要基于密集的交通工业设施、高投入的农业生产等情况,以人类生活产生的氮排放为切入点,研究了浙江省氮排放变化及时空氮排放差异、降氮潜力和规模,以及氮排放驱动因素。结果表明:氮排放量以杭州、宁波、温州、嘉兴、湖州、绍兴和金华地区居高;杭州、宁波、温州、嘉兴为降氮规模最大的地区,对浙江省可降氮量有较强的拉动力;提高环境治理强度及科研投资力度、优化能耗、产业与对外贸易开放结构、合理控制工业化水平,对降低氮排放有积极作用。

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	吕越
	陈忠清

关键词 ：氮排放, 降氮潜力和规模, 驱动因素, 浙江

Abstract：Based on concentrated traffic industry and intense agriculture in Zhejiang province and taking the nitrogen(N)emissions from human life as the breakthrough point,the temporal trend of N emissions,N reduction potential,the scale of each province,and the driving factors of N emissions were studied.The results indicate that:Hangzhou,Ningbo,Wenzhou,Jiaxing,Huzhou,Shaoxing and Jinhua are high N emissions areas;Hangzhou,Ningbo,Wenzhou and Jiaxing are the areas with largest scale of N reduction,which had a strong pull power to reduce N emissions in Zhejiang;Enhancing environmental governance and research investment intensity,optimizing the structure of consumption,industry and opening-up foreign trade,and controlling reasonably industrialization level have positive effect on reducing N emissions

Key words： Nitrogen emissions Nitrogen reduction potential and size Driving factor Zhejiang province

收稿日期: 2015-10-08

PACS:

X32

基金资助:绍兴文理学院科研启动项目(20145013、20155010)。

作者简介: 吕越(1982-),女,浙江绍兴人,博士,讲师;研究方向:生态环境与可持续发展。

引用本文:

吕越, 陈忠清. 氮排放量评估及降氮潜力研究——以浙江省为例[J]. 中国科技论坛, 2016(6): 102-107.
Lyn Yue, Chen Zhongqing. Study on Nitrogen Emissions Evaluation and Nitrogen Reduction Potential:A Case Study of Zhejiang. , 2016(6): 102-107.

链接本文:

http://www.zgkjlt.org.cn/CN/Y2016/I6/102

[1]薛建福,濮超,张冉,等.农作措施对中国稻田氧化亚氮排放影响的研究进展[J].农业工程学报,2015,31(11):1-9.
[2]樊庆锌,孟婷婷,李金梦,等.江川灌区旱田改水田加剧水体氮磷污染[J].农业工程学报,2014,30(12):79-86.
[3]方华军,程淑兰,于贵瑞,等.森林土壤氧化亚氮排放对大气氮沉降增加的响应研究进展[J].土壤学报,2015,52(2):262-271.
[4]TAN X M,HUANG S,XIONG C,et al.Studies on the influences of different planting patterns on the emissions of methane and nitrous oxide in the paddy field[J].Agricultural science & technology,2015,16(5):968-972.
[5]蔡睿堃,邓玉,倪福全,等.农村饮用水水源氮污染及健康风险的时空变化特征研究:以名山区为例[J].四川大学学报(工程科学版),2015,47(2):40-46.
[6]赵银慧,李莉娜,景立新,等.污水处理厂氮排放特征[J].中国环境监测,2015,31(4):58-61.
[7]岳建华,杨水文.海南省松涛水库流域典型生活垃圾总氮静态溶出规律研究[J].中国环境科学,2013,33(s1):2-6.
[8]BRUNA G,UGO P,LUIS L,et al.The contribution of food waste to global and European nitrogen pollution[J].Environmental science and policy,2013(3):186-195.
[9]SHI Y,XIA Y F,LU B H,et al.Emission inventory and trends of N for China,2000—2020[J].Journal of Zhejiang university-science a(applied physics & engineering),2014,15(6):454-465.
[10]CHEN D,FU X Q,WANG C,et al.Nitrous oxide emissions from a masson pine forest soil in subtropical central China[J].Pedosphere,2015,25(2):263-274.
[11]闫兰玲,徐海岚,唐伟,等.城市大气污染物排放与产业发展关系研究:基于杭州市EKC曲线的实证分析[J].中国人口·资源与环境,2014,24(5):147-150.
[12]WANG F F,DING Y H,GE L,et al.Effect of high-strength ammonia nitrogen acclimation on sludge activity in sequencing batch reactor[J].Journal of environmental sciences,2010,22(11):1683-1690.
[13]GALLOWAY J N,COWLING E B.Reactive nitrogen and the world:200 years of change[J].Ambio:a journal of the human environment,2002,31(2):64-71.