[1]傅舜宇,张青,陶宇,等.香榧幼林开垦对绍兴汤浦水库氮输入的影响[J].浙江林业科技,2021,41(06):15-23.[doi:10.3969/j.issn.1001-3776.2021.06.003]
 FU Shun-yu,ZHANG Qing,TAO Yu,et al.Effect of Young Torreya grandis ‘Merrillii’ Plantation on Nitrogen Input in Tangpu Reservoir of Shaoxing[J].Journal of Zhejiang Forestry Science and Technology,2021,41(06):15-23.[doi:10.3969/j.issn.1001-3776.2021.06.003]
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香榧幼林开垦对绍兴汤浦水库氮输入的影响()
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《浙江林业科技》[ISSN:1001-3776/CN:33-1112/S]

卷:
41
期数:
2021年06期
页码:
15-23
栏目:
出版日期:
2021-12-10

文章信息/Info

Title:
Effect of Young Torreya grandis ‘Merrillii’ Plantation on Nitrogen Input in Tangpu Reservoir of Shaoxing
文章编号:
1001-3776(2021)06-0015-09
作者:
傅舜宇张青陶宇鲍依群
(绍兴市水环境科学研究院有限公司,浙江 绍兴 312000)
Author(s):
FU Shun-yuZHANG QingTAO YuBAO Yi-qun
(Shaoxing Water Environment Research Institute Co., Ltd of Zhejiang, Shaoxing 312000, China)
关键词:
香榧汤浦水库总氮SWAT模型径流小区
Keywords:
Torreya grandis ‘Merrillii’ Tangpu Reservoir total nitrogen SWAT model runoff plot
分类号:
X171.1
DOI:
10.3969/j.issn.1001-3776.2021.06.003
文献标志码:
A
摘要:
2016—2018年,本研究对香榧Torreya grandis‘Merrillii’幼林,特别是开垦形成的香榧幼林对汤浦水库流域的非点源氮输入的影响进行研究,旨在为保护水库水质和非点源污染治理提供依据;基于SWAT模型对汤浦水库的氮输入进行了模拟,对上游流域非点源污染的关键区域和对入库氮贡献最大的土地利用方式进行了识别;设计了针对香榧幼林的径流小区试验;径流小区试验和上游河道断面的水质数据被共同用作校准SWAT模型对香榧集中种植区对入库氮贡献的模拟结果。研究结果表明:南溪南部榆树支流、竹溪支流上游等香榧集中种植区是汤浦水库流域非点源氮污染的关键区域;占流域面积约6%的香榧幼林可提供约45%的入库总氮,是对入库总氮贡献最大的土地利用方式。
Abstract:
During 2016 and 2018, investigations were carried out on Tangpu Reservoir basin, especially on plantation of young Torreya grandis ‘Merrillii’ on non-point source nitrogen input in the reservoir. The nitrogen input in Tangpu Reservoir was simulated by SWAT model, the key areas of non-point source pollution in upstream and the landuse type which contributed the most to the nitrogen input were identified. The runoff plot experiment was implemented in young T. grandis ‘Merrillii’ plantation. The water quality data of runoff plot experiment and upstream river sections were used to calibrate the simulation results of the contribution of T. grandis ‘Merrillii’ plantation on nitrogen input in the SWAT model. The result of SWAT model simulation showed that young T. grandis ‘Merrillii’ plantations was the key areas of non-point source nitrogen pollution in Tangpu Reservoir basin. 6% of the total basin area contributed 45% of nitrogen input into Tangpu Reservoir.

参考文献/References:

[1] 戴文圣,黎章矩,程晓建,等. 香榧林地土壤养分状况的调查分析[J]. 浙江林学院学报,2006,2:140-144.
[2] ZHENG H,LIU Z,ZUO J,et al. Characteristics of nitrogen loss through surface-subsurface flow on red soil slopes of southeast China[J]. Euras Soil Sc.,2017,50:1506-1514.
[3] MALIN S,HARAPIAK J,NYBORG M,et al. Effects of long-term applications of various nitrogen sources on chemical soil properties and composition of bromegrasshay[J]. Plant Nutr,2000,23:903-912.
[4] ZHANG W,XU M,WANG B,et al. Soil organic carbon, total nitrogen and grain yields under long-term fertilizations in the upland red soil of southern China[J]. Nutr Cycl Agroecosyst,2009,84(1):59-69.
[5] 宋洋,廖亮,刘涛,等. 不同遮荫水平下香榧苗期光合作用及氮分配的响应机制[J]. 林业科学,2016,52(5):55-63.
[6] 程晓建,黎章矩,喻卫武,等. 榧树的资源分布与生态习性[J]. 浙江林学院学报,2007,4:383-388.
[7] CHEN X W,NIU J Z. Evaluating the adaptation of Chinese Torreya plantations to climate change[J]. Atmosphere,2020,11(2):176.
[8] 叶伟华,宋其岩,杜国坚. 生态经营对香榧生长和土壤生态的影响[J]. 浙江农业科学,2020,8:1546-1547,1611.
[9] 陈岗,宋其岩,胡德胜. 套种旱稻对香榧林地土壤生态的影响[J]. 浙江农业科学,2020,61(3):498-499,508.
[10] 姚芳,张春苗,赵科理,等. 香榧林地土壤肥力和植物养分状况时空动态[C]. 中国土壤学会第十二次全国会员代表大会暨第九届海峡 两岸土壤肥料学术交流研讨会论文集,2012,1286-1287.
[11] CHEN X,XIAO P,NIU J,et al. Evaluating soil and nutrients (C, N, and P) loss in Chinese Torreya plantations[J]. Environ Pollut,2020:263.
[12] 杨福培,鲁柏良. 绍兴市土地志(内部资料)[R]. 绍兴市土地管理局,1993:240-244.
[13] 魏孝孚. 浙江土种志[M]. 杭州:浙江科学技术出版社,1993:4-5,15-18,41-43,55-56,63-64.
[14] 施练东,俞海平,朱建坤,等. 基于SWAT模型的汤浦水库流域非点源污染模拟[J]. 水生态学杂志,2011,32(3):66-70.
[15] 石雯倩. 汤浦水库流域水质变化及污染物总量控制模拟[D]. 杭州:浙江大学,2014:86-87.
[16] 周晓燕,童秀华,蔡海江,等. 2015—2016年度汤浦水库污染源调查(内部资料)[R]. 绍兴市汤浦水库有限公司及绍兴市水环境科学 研究院有限公司,2016.
[17] 刘会萍. 汤浦水库流域非点源污染负荷估算(内部资料)[R]. 绍兴市汤浦水库有限公司,2017:65-66.
[18] 张丽萍,付兴涛,吴希媛. 竹林坡地径流中泥沙及氮磷载荷特征模拟[J]. 应用生态学报,2012,23(04):881-888.
[19] 王小明,王刚,周本智,等. 中亚热带天然次生常绿阔叶林水文生态效应研究[J]. 水土保持通报,2011,31(01):11-15.
[20] 朱少威. 西苕溪流域经济林土壤侵蚀和稻田养分流失控制技术的研究[D]. 杭州:浙江大学,2016:20-23.
[21] 赵越,李泽利,刘茂辉,等. 模拟降雨条件下坡度对茶园红壤氮素流失影响[J]. 农业环境科学学报,2014,33(05):992-998.
[22] 尹微琴,王小治,王爱礼,等. 太湖流域农村生活污水污染物排放系数研究——以昆山为例[J]. 农业环境科学学报,2010,29(7): 1369-1373.
[23] MARIET M H,JEAN-CHRISTOPHE C,PIOTR B,et al. The role of vegetation and litter in the nitrogen dynamics of riparian buffer zones in Europe[J]. Ecol Engin,2005,24(5):465-482.
[24] MAR?A F R,COVADONGA P,SASKIA K,et al. Splash erosion: A review with unanswered questions[J]. Earth-Sci Rev,2017:171.
[25] 黄程鹏,吴家森,许开平,等. 不同施肥山核桃林氮磷径流流失特征[J]. 水土保持学报,2012,26(1):43-46,52.

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备注/Memo

备注/Memo:
收稿日期:2021-05-09;修回日期:2021-8-12
作者简介:傅舜宇,工程师,从事水源地保护和富营养化治理研究工作;E-mail:383471068@qq.com。
更新日期/Last Update: 2021-12-01