非参数核密度估计在铜、银物种敏感度分布中的应用

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摘要

采用非参数核密度估计模型构建铜和银保护中国淡水水生生物的物种敏感度分布曲线，并推导了它们的水质基准阈值.结果表明，非参数核密度估计方法在推导IB族两种过渡金属水质基准中的稳健性和精确度都大大优于传统参数模型，能够更好地构建物种敏感度分布曲线. 针对不同类别的物种来看，脊椎动物、无脊椎动物、鱼类、甲壳类、其他无脊椎动物和全部水生生物的HC5值都随着周期增加而减小，无脊椎动物的敏感性明显高于高营养级的脊椎动物.非参数核密度估计方法的提出丰富了水质基准的理论方法学，为同族或同周期元素之间水质基准阈值的进一步研究和更好地保护水生生物提供了有力的支撑.

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	王颖
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	吴丰昌

关键词 ：铜, 银, 淡水水生生物水质基准, 非参数核密度估计, 物种敏感度分布

Abstract：

Species sensitivity distribution curves of copper and silver were constructed using non-parametric kernel density estimation model to protect Chinese freshwater aquatic life, and then their water quality criteria thresholds were derived. The results showed that the robustness and accuracy of non-parametric kernel density estimation method are superior to the traditional parameters models to derive water quality criteria for two transition metals of Group IB. After comparing different taxa of two metals, we found that HC5values of vertebrates, invertebrates, fish, crustaceans, other invertebrates and all aquatic organisms were inversely proportional to atomic number. The sensitivity of invertebrates was significantly higher than that of vertebrates at high trophic level. The proposed method enriched the methodological foundation for water quality criteria and provided an alternative approach for developing SSDs of the same group and period elements to support for protection of aquatic organisms.

Key words： copper silver freshwater quality criteria non-parametric kernel density estimation species sensitivity distribution

收稿日期: 2016-09-01

PACS:

X171.5

基金资助:

国家自然科学基金项目（41503100，41603111）；创新研究群体项目（41521003）；环境基准与风险评估国家重点实验室开放课题（SKLECRA201649）；中国博士后科学基金项目（2016M601094）

通讯作者: 冯承莲,副研究员,fengchenglian@163.com E-mail: fengchenglian@163.com

作者简介: 王颖(1989-),女,陕西西安人,助理研究员,博士,主要从事水质基准理论与方法学和预测毒理学研究.发表论文10篇.

引用本文:

王颖, 冯承莲, 穆云松, 何佳, 郄玉, 吴丰昌. 非参数核密度估计在铜、银物种敏感度分布中的应用[J]. 中国环境科学, 2017, 37(4): 1548-1555. WANG Ying, FENG Cheng-lian, MU Yun-song, HE Jia, QIE Yu, WU Feng-chang. Application of non-parametric kernel density estimation for developing species sensitivity distributions of copper and silver. CHINA ENVIRONMENTAL SCIENCECE, 2017, 37(4): 1548-1555.

链接本文:

http://manu36.magtech.com.cn/Jweb_zghjkx/CN/ 或 http://manu36.magtech.com.cn/Jweb_zghjkx/CN/Y2017/V37/I4/1548

[1]	吴丰昌,冯承莲,曹宇静,等.我国铜的淡水生物水质基准研究[J]. 生态毒理学报, 2011,6(6):617-628.
[2]	马燕,吴丰昌,谭伟强,等.影响银淡水生物水质基准的环境因素分析[J]. 生态毒理学报, 2015,10(1):235-244.
[3]	孟伟,吴丰昌.水质基准的理论与方法学导论[M]. 北京:科学出版社, 2010.
[4]	U S EPA. Quality criteria for water[R]. Washington, DC, USA:National Technical Information Service, 1976.
[5]	Kooijman S. A safety factor for LC50 values allowing for differences in sensitivity among species[J]. Water Research, 1987,21(3):269-276.
[6]	Posthuma L, Suter G, TP T. Species sensitivity distributions in ecotoxicology[M]. Lewis, Boca Raton, FL:CRC press, 2002.
[7]	Van Vlaardingen P, Traas T, Wintersen A, et al. Etx2. 0. A program to calculate hazardous concentrations and fraction affected, based on normally-distributed toxicity data, RIVM report (and software)[R]. The Netherlands:National Institute for Public Health and the Environment, 2004.
[8]	Pennington D W. Extrapolating ecotoxicological measures from small data sets[J]. Ecotoxicology and Environmental Safety, 2003,56(2):238-250.
[9]	闫振广,孟伟,刘征涛,等.辽河流域氨氮水质基准与应急标准探讨[J]. 中国环境科学, 2011,31(11):1829-1835.
[10]	洪鸣,王菊英,张志锋,等.海水中金属铅水质基准定值研究[J]. 中国环境科学, 2016,36(2):626-633.
[11]	王颖,冯承莲,黄文贤,等.物种敏感度分布的非参数核密度估计模型[J]. 生态毒理学报, 2015,10(1):215-224.
[12]	Newman M C, Ownby D R, Mezin L C, et al. Applying species-sensitivity distributions in ecological risk assessment:assumptions of distribution type and sufficient numbers of species[J]. Environmental Toxicology and Chemistry, 2000,19(2):508- 515.
[13]	陈波宇,郑斯瑞,牛希成,等.物种敏感度分布及其在生态毒理学中的应用[J]. 生态毒理学报, 2010,5(4):1673-5897.
[14]	潘海涛. Bootstrap方法在非参数核估计中的研究与应用[J]. 统计与决策, 2011,(23):22-24.
[15]	Rosenblatt M. Remarks on some nonparametric estimates of a density function[J]. The Annals of Mathematical Statistics, 1956,27(3):832-837.
[16]	Wang Y, Wu F C, Giesy J P, et al. Non-parametric kernel density estimation of species sensitivity distributions in developing water quality criteria of metals[J]. Environmental Science and Pollution Research, 2015,22(18):13980-13989.
[17]	Wang Y, Feng C, Liu Y, et al. Comparative study of species sensitivity distributions based on non-parametric kernel density estimation for some transition metals[J]. Environmental Pollution, 2017,221:343-350.
[18]	Wu F C, Mu Y S, Chang H, et al. Predicting water quality criteria for protecting aquatic life from physicochemical properties of metals or metalloids[J]. Environmental Science & Technology, 2013,47(1):446-453.
[19]	冯承莲,吴丰昌,赵晓丽,等.水质基准研究与进展[J]. 中国科学:地球科学, 2012,42(5):657-664.
[20]	吴丰昌,冯承莲,张瑞卿,等.我国典型污染物水质基准研究[J]. 中国科学:地球科学, 2012,42(5):665-672.
[21]	Solomon K, Giesy J, Jones P. Probabilistic risk assessment of agrochemicals in the environment[J]. Crop Protection, 2000, 19(8):649-655.
[22]	Solomon K R, Baker D B, Richards R P, et al. Ecological risk assessment of atrazine in North American surface waters[J]. Environmental Toxicology and Chemistry, 1996,15(1):31-76.
[23]	Giesy J P, Solomon K R, Coats J R, et al. Chlorpyrifos:ecological risk assessment in North American aquatic environments[M]. New York:Springer, 1999.
[24]	Campbell K R, Bartell S M, Shaw J L. Characterizing aquatic ecological risks from pesticides using a diquat dibromide case study. II. Approaches using quotients and distributions[J]. Environmental Toxicology and Chemistry, 2000,19(3):760-774.
[25]	TenBrook P L, Palumbo A J, Fojut T L, et al. The University of California-Davis Methodology for deriving aquatic life pesticide water quality criteria[J]. Reviews of Environmental Contamination and Toxicology, 2010:1-155.
[26]	Vardy D W, Tompsett A R, Sigurdson J L, et al. Effects of subchronic exposure of early life stages of white sturgeon (Acipenser transmontanus) to copper, cadmium, and zinc[J]. Environmental Toxicology and Chemistry, 2011,30(11):2497- 2505.
[27]	Parzen E. On estimation of a probability density function and mode[J]. The Annals of Mathematical Statistics, 1962:1065- 1076.
[28]	吴喜之.非参数统计[M]. 北京:中国统计出版社, 1999.
[29]	陈希孺,柴根象.非参数统计教程[M]. 上海:华东师范大学出版社, 1993.
[30]	Prakasa Rao B. Nonparametric functional estimation[M]. New York:Academic Press, 1983.
[31]	Epanechnikov V A. Non-parametric estimation of a multivariate probability density[J]. Theory of Probability & Its Applications, 1969,14(1):153-158.
[32]	李竹渝,鲁万波,龚金国.经济,金融计量学中的非参数估计技术[M]. 北京:科学出版社, 2007.
[33]	颜伟,任洲洋,赵霞,等.光伏电源输出功率的非参数核密度估计模型[J]. 电力系统自动化, 2013,37(10):35-40.
[34]	Liu Y D, Wu F C, Mu Y S, et al. Setting water quality criteria in China:approaches for developing species sensitivity distributions for metals and metalloids[J]. Reviews of Environmental Contamination and Toxicology, 2014,230:35-57.
[35]	Van Straalen N M, Denneman C A. Ecotoxicological evaluation of soil quality criteria[J]. Ecotoxicology and Environmental Safety, 1989,18(3):241-251.
[36]	U.S.EPA. Methods/indicators for determining when metals are the cause of biological impairments of rivers and streams:species sensitivity distributions and chronic exposure- response relationships from laboratory data[R]. Cincinnati, OH, USA:Office of Research and Development, 2005.
[37]	Van Sprang P A, Verdonck F A, Vanrolleghem P A, et al. Probabilistic environmental risk assessment of zinc in Dutch surface waters[J]. Environmental Toxicology and Chemistry, 2004,23(12):2993-3002.
[38]	Grist E P, Leung K M, Wheeler J R, et al. Better bootstrap estimation of hazardous concentration thresholds for aquatic assemblages[J]. Environmental Toxicology and Chemistry, 2002, 21(7):1515-1524.
[39]	Haynes W M. CRC handbook of chemistry and physics[M]. Lewis, Boca Raton, FL:CRC press, 2012.
[40]	余德才,曹文娟,余旭东.原子核强度电势和原子价层电量对元素电负性的标度[J]. 物理化学学报, 2009,25(1):155-160.
[41]	Walker J D, Enache M, Dearden J C. Quantitative cationic- activity relationships for predicting toxicity of metals[J]. Environmental Toxicology and Chemistry, 2003,22(8):1916- 1935.
[42]	孔祥臻,何伟,秦宁,等.重金属对淡水生物生态风险的物种敏感性分布评估[J]. 中国环境科学, 2011,31(9):1555-1562.
[43]	U.S.EPA. National Recommended Water Quality Criteria[R]. Washington, DC, USA:Office of Science and Technology, 2012.
[44]	Brock T, Arts G H, Maltby L, et al. Aquatic risks of pesticides, ecological protection goals, and common aims in European Union legislation[J]. Integrated Environmental Assessment and Management, 2006,2(4):e20-e46.