Influence factors, correction mode and method of heavy metal detection in Pxrf soil
CHEN Zeng-si-che1,2, XU Ya1, LEI Guo-yuan2, LIU Yu-qiang1, LIU Jing-cai1, YAO Guang-yuan1, HUANG Qi-fei1
1. State Key Laboratory of Environmental Benchmarks and Risk Assessment and Research Institute of Solid Waste Management, Chinese Research Academy of Environment Sciences, Beijing 100012, China;
2. Industrial Safety Engineering Technology Research Center of Hubei Province, Wuhan University of Science and Technology Wuhan 430081, China
In view of the problem that the portable X-ray fluorescence (pxrf) method is not accurate enough for the determination of heavy metals in soil, a general modeling method and process based on the relationship between the measured value of Pxrf and the characteristics of the site parameters are proposed, which is used to build a Pxrf correction model suitable for the characteristics of each site, so as to improve the measurement accuracy of Pxrf. Taking a typical mining area in Beijing as an example, By analyzing the correlation of potentially related factors (i.e., soil organic matter content, water content, and actual pollutant content) and different mathematical transformations of these factors (i.e., index, logarithm, and power function) with the measured values of Pxrf, we identified the influencing variables, influence degrees, and influence forms that significantly affect the measured values of Pxrf. Based on the identification of influencing factors, we established the mathematical model of Pxrf to achieve the purpose of correcting the measured value of pxrf and improving the accurate value. The results showed that the measured values of Pb, Cu and Zn were significantly correlated with the actual concentrations, and the correlation coefficients were 0.75~0.82; the correlation coefficients of Sr, Fe and Mn were 0.25~0.52, with slightly poor correlation. The influence of water content on the detection of Pxrf was in order of Sr, Mn, Cu, Pb, Zn, the correlation coefficient range was 0.1~0.7. The Pxrf of all heavy metals is weakly affected by the content of soil organic matter, and the correlation coefficient was lower than 0.5. After the model transformation, the correlation between the Pxrf of heavy metals Zn, Pb, Cu and the actual concentration increases (increased by 4%~13%); other heavy metals had no significant change. The model verification results showed that the correlation between the Pxrf of four heavy metals Pb, Zn, Cu, Mn Compared with the original Pxrf measurement, the relative error of the corrected Pxrf value in the model could be reduced from 32.4%~56.6% to 4%~29.9%.
陈曾思澈, 徐亚, 雷国元, 刘玉强, 刘景财, 姚光远, 黄启飞. Pxrf土壤重金属检测的影响因素、模式与校正方法[J]. 中国环境科学, 2020, 40(2): 708-715.
CHEN Zeng-si-che, XU Ya, LEI Guo-yuan, LIU Yu-qiang, LIU Jing-cai, YAO Guang-yuan, HUANG Qi-fei. Influence factors, correction mode and method of heavy metal detection in Pxrf soil. CHINA ENVIRONMENTAL SCIENCECE, 2020, 40(2): 708-715.
Taylor P D, Ramsey M H, Potts P J. Balancing measurement uncertainty against financial benefits:comparison of in situ and ex situ analysis of contaminated land[J]. Environmental Science & Technology, 2004,38(24):6824-6831.
[2]
Bruno Lemière. A review of pXRF (Field Portable X-ray Fluorescence) applications for applied geochemistry[J]. Journal of Geochemical Exploration, 2018,188:350-363.
[3]
Huang J, Malone B P, Minasny B, et al. Evaluating a Bayesian modelling approach (INLA-SPDE) for environmental mapping[J]. Science of the Total Environment, 2017,609:621-632.
[4]
徐亚,刘玉强,能昌信,等.基于概率风险分析的填埋场安全防护距离研究[J]. 中国环境科学, 2017,37(7):2786-2792. Xu Y, Liu Y Q, Nai C X, et al. A probabilistic risk-based method to determine the safety protection distance for solid waste landfill[J]. China Environmental Science, 2017,37(7):2786-2792.
[5]
柳伟,许伟,孙东,等.便携式XRF仪现场快速测定土壤中Pb的可行性研究[J]. 安徽农业科学, 2017,45(33):115-117. Liu W, Xu W, Sun D.et al. Discussion on feasibility of rapid testing of Pb in soil by portable XRF analyzer in field[J]. Journal of Anhui Agricultural Sciences, 2017,45(33):115-117.
[6]
Shuttleworth E L, Evans M G, Hutchinson S M, et al. Assessment of Lead Contamination in Peatlands Using Field Portable XRF[J]. Water, Air, & Soil Pollution, 2014,225(2):1844.
[7]
Ravansari R, Lemke L D. Portable X-ray fluorescence trace metal measurement in organic rich soils:pXRF response as a function of organic matter fraction[J]. Geoderma, 2018,319:175-184.
[8]
Andrew T, Alex T. On site determination of trace metals in estuarine sediments by field-portable-XRF[J]. Talanta, 2018,190:498-506.
[9]
Caporale A G, Paola A, Fiore C, et al. Monitoring metal pollution in soils using portable-XRF and conventional laboratory-based techniques:Evaluation of the performance and limitations according to metal properties and sources[J]. Science of the Total Environment, 2018,643:516-526.
[10]
Rouillon M, Taylor M P, Dong C. Reducing risk and increasing confidence of decision making at a lower cost:In-situ pXRF assessment of metal-contaminated sites[J]. Environmental Pollution, 2017,229:780.
[11]
Kim H R, Kim K H, Yu S, et al. Better assessment of the distribution of As and Pb in soils in a former smelting area, using ordinary co-kriging and sequential Gaussian co-simulation of portable X-ray fluorescence (PXRF) and ICP-AES data[J]. Geoderma, 2019,341:26-38.
[12]
徐亚,薛祥山,刘玉强,等.地下水观测井井筒效应的多场耦合数值模拟[J]. 地球科学(中国地质大学学报), 2014,39(9):1349-1356. Xu Y, Xue X S, Liu Y Q. et al. A coupled darcy-brinkman-NS simultation model of wellbore effect of an monitor well[J]. Earth Science, 2014,39(9):1349-1356.
[13]
HJ/T 166-2004土壤环境监测技术规范[S]. HJ/T 166-2004 The technical specification for soil environmental monitoring[S].
[14]
徐亚,能昌信,刘峰,等.填埋场长期渗漏的环境风险评价方法与案例研究[J]. 环境科学研究, 2015,28(4):605-612. Xu Y, Nai C X, Liu F. et al. Method and case study to evaluate long-term environmental risks from landfill leakage[J]. Research of Environmental Sciences, 2015,28(4):605-612.
[15]
侯振辉,王晨香.电感耦合等离子体质谱法测定地质样品中35种微量元素[J]. 中国科学技术大学学报, 2007,(8):940-944. Hou Z H, Wang C X. Determination of 35 trace elements in geological samples by inductively coupled plasma mass spectrometry[J]. Journal of University of Science and Technology of China, 2007,(8):940-944.
[16]
段雪梅,张燕波,文军,等.便携式XRF土壤重金属检测仪在环境应急监测中的应用探讨[J]. 环境监测管理与技术, 2017,29(3):49-52. Duan X M, Zhang Y B, Wen J, et al. A Study on application of portable XRF instrument for heavy metal measuring in environmental emergency monitoring[J]. The Administration and Technique of Environmental Monitoring, 2017,29(3):49-52.
[17]
胡明情.便携式XRF仪在土壤重金属检测中的应用[J]. 环境科学与技术, 2015,38(S2):269-272. Hu M Q. Application of portable X-Ray fluorescence spectrometer analyzer in field detection of heavy metal[J]. Environmental Science & Technology, 2015,38(S2):269-272.
[18]
杨桂兰,商照聪,李良君,等.便携式X射线荧光光谱法在土壤重金属快速检测中的应用[J]. 应用化工, 2016,45(8):1586-1591. Yang G L, Shang Z C, Li L J. et al. Application of portable-XRF spectrometry for rapid determination of common heavy metals in soil[J]. Applied Chemical Industry, 2016,45(8):1586-1591.
[19]
邝荣禧,胡文友,何跃,等.便携式X射线荧光光谱法(PXRF)在矿区农田土壤重金属快速检测中的应用研究[J]. 土壤, 2015,47(3):589-595. Kuang R X, Hu W Y, He Y, et al. Application of portable X-ray fluorescence spectrometry (PXRF) in rapid detection of heavy metals in farmland soils[J]. Soils, 2015,47(3):589-595.
[20]
HJ613-2011土壤干物质和水分的测定重量法[S]. HJ613-2011 Soil-Determination of dry matter and water content-Gravimetric method.[S].
[21]
HJ761-2015固废物有机质的测定灼烧减量法[S]. HJ761-2015 Soild waste-Determination of organic matter-Ignition loss method[S].
[22]
徐亚,能昌信,刘玉强,等.基于环境风险的危险废物填埋场安全寿命周期评价[J]. 中国环境科学, 2016,36(6):1802-1809. Xu Y, Nai C X, Liu Y Q, et al. Risk-based method to assess the safe life of hazardous waste landfill[J]. China Environmental Science, 2016,36(6):1802-1809.
[23]
Turner A, Poon H, Taylor A, et al. In situ determination of trace elements in, Fucus, spp. by field-portable-XRF[J]. Science of the Total Environment, 2017,593-594:227-235.
[24]
彭洪柳,杨周生,赵婕,等.高精度便携式X射线荧光光谱仪在污染农田土壤重金属速测中的应用研究[J]. 农业环境科学学报, 2018,37(7):1386-1395. Peng H L, Yang Z S, Zhao J, et al. Use of high-precision portable X-ray fluorescence spectrometer on the heavy metal rapid determination for contaminated agricultural soils[J]. Journal of Agro-Environment Science, 2018,37(7):1386-1395.
[25]
胡昊.ICP-MS分析《全国土壤污染状况详查》土壤中9种金属元素[J]. 世界有色金属, 2019,(11):273-274. Hu H. Determination of 9 heavy metal in the sample of national detailed soil pollution investigation by ICP-MS[J]. World Nonferrous Metals, 2019,(11):273-274.