|
|
|
|
|
|
| Research on the Valence State Analysis Method of Selenium in Soil and Stream Sediment |
| CHEN Hai-jie1, 2, MA Na1, 2, BO Wei1, 2, ZHANG Ling-huo1, 2, BAI Jin-feng1,2, SUN Bin-bin1, 2, ZHANG Qin1, 2, YU Zhao-shui1, 2* |
1. Key Laboratory of Geochemical Exploration,Ministry of Natural Resources,Langfang 065000,China
2. Institute of Geophysical and Geochemical Exploration,Chinese Academy of Geological Sciences,Langfang 065000,China |
|
|
|
|
Abstract The study on the valence state of selenium in soil and stream sediment contributes to understanding the migration and transformation of selenium (Se). At present, there are many methods on the research of valence state of Se extracted partly from soil and stream sediment, but how to determine the valence state of all Se is still a difficult problem and the difficulty lies in how to digest Se in soil and stream sediment completely with valence state unchanged. The research showed that Se(Ⅵ) could be reduced to Se(Ⅳ) by 6.0 mol·L-1 HCl and the valence state of Se(Ⅳ) and Se(Ⅵ) stayed stable in 1.2 mol·L-1 HCl solution for 48 h at room temperature. Se, in soil and stream sediment, is digested with HNO3+HF+HClO4 completely and the valence state of Se(Ⅳ) and Se(Ⅵ) was unchanged when the HClO4 heated to white smoke appeared, but after the HClO4 heated to dryness, Se(Ⅳ) will all be oxidized to Se(Ⅵ). The method to determine Se(Ⅳ) and Se(Ⅵ) in soil and stream sediment by hydride generation-atomic fluorescence spectroscopy(HG-AFS) was developed based on this research, and the samples were digested with HNO3+HF+HClO4 and heated to white smoke appeared, then stopped heating (to avoid local heating to dry). After the digestion, the samples which cool down to room temperature were dissolved with 1.2 mol·L-1 HCl, and Se(Ⅳ) can be detected by HG-AFS. The Se(Ⅵ) will all be reduced to Se(Ⅳ) by being heated in 6.0 mol·L-1 HCl solvent, and then total Se can be detected by HG-AFS, from the total quantities minus the Se(Ⅳ) concentration we obtained the Se(Ⅵ) concentration. The results show that Se in soil and stream sediment is digested completely and the valence state of Se(Ⅳ) and Se(Ⅵ) stayed stable. The detection limits of Se(Ⅳ) and total Se were 4.5 and 5.1 ng·g-1, respectively. The recovery rate of Se(Ⅳ) and Se(Ⅵ) was 102%~108% and 94%~104%.
|
|
Received: 2020-01-21
Accepted: 2020-04-29
|
|
|
|
Corresponding Authors:
YU Zhao-shui
E-mail: yzs2006@163.com
|
|
[1] Longchamp M, Castrec-Rouelle M, Biron P, et al. Food Chemistry, 2015, 182: 128.
[2] De Feudis M, D’Amato R, Businelli D, et al. Science of the Total Environment, 2019, 659: 131.
[3] Zhang H, Zhao Z, Zhang X, et al. Food Chemistry, 2019, 286: 550.
[4] Tadayon F, Mehrandoost S. Journal of Analytical Chemistry, 2015, 70(11): 1336.
[5] Wang C, He M, Chen B, et al. Talanta, 2018, 188: 736.
[6] Barache U B, Shaikh A B, Lokhande T N, et al. Journal of Environmental Chemical Engineering, 2017, 5(5): 4828.
[7] Grijalba A C, Fiorentini E F, Wuilloud R G. Journal of Chromatography A, 2017, 1491: 117.
[8] Nyaba L, Matong J M, Dimpe K M, et al. Talanta, 2016, 159: 174.
[9] Kalantari H, Manoochehri M. Microchimica Acta, 2018, 185(3): 196.
[10] Xie X, Feng C, Ye M, et al. Food Analytical Methods, 2015, 8(7): 1739.
[11] Shishov A, Wieczorek M, Kos′cielniak P, et al. Talanta, 2018, 181: 359.
[12] Fu J, Xu Z, Qian S, et al. Talanta, 2012, 94(6): 167.
[13] SHI Tian-ping, LIANG Shu-ting(石天平, 梁述廷). Geology of Anhui(安徽地质), 2019, 29(1): 69.
[14] WU Shao-wei, CHI Quan(吴少尉, 池 泉). Journal of Hubei Minzu University·Natural Science Edition(湖北民族学院学报·自然科学版), 2003, 21(1): 52.
[15] XUE Chao-qun, GUO Min(薛超群, 郭 敏). Rock and Mineral Analysis(岩矿测试), 2012, 31(6): 980.
[16] LÜ Li, LI Yuan, JING Mei-jiao, et al(吕 莉,李 源,井美娇,等). Spectroscopy and Spectral Analysis (光谱学与光谱分析), 2019, 39(2): 607.
[17] Long Z, Luo Y, Zheng C, et al. Applied Spectroscopy Reviews, 2012, 47(5): 382.
[18] Long Z, Chen C, Hou X, et al. Applied Spectroscopy Reviews, 2012, 47(7): 495.
[19] GUO Ying-chao, MA Chun-hong, CUI Xiao-ying, et al(郭颖超, 马春红, 崔晓英,等). Xinjiang Nonferrous Metals(新疆有色), 2018, 41(3): 92. |
| [1] |
XU Tian1, 2, LI Jing1, 2, LIU Zhen-hua1, 2*. Remote Sensing Inversion of Soil Manganese in Nanchuan District, Chongqing[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 69-75. |
| [2] |
LI Hu1, ZHONG Yun1, 2, FENG Ya-ting1, LIN Zhen1, ZHU Shi-jiang1, 2*. Multi-Vegetation Index Soil Moisture Inversion Model Based on UAV
Remote Sensing[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 207-214. |
| [3] |
HAN Xue1, 2, LIU Hai1, 2, LIU Jia-wei3, WU Ming-kai1, 2*. Rapid Identification of Inorganic Elements in Understory Soils in
Different Regions of Guizhou Province by X-Ray
Fluorescence Spectrometry[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 225-229. |
| [4] |
MENG Shan1, 2, LI Xin-guo1, 2*. Estimation of Surface Soil Organic Carbon Content in Lakeside Oasis Based on Hyperspectral Wavelet Energy Feature Vector[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3853-3861. |
| [5] |
LI Qi-chen1, 2, LI Min-zan1, 2*, YANG Wei2, 3, SUN Hong2, 3, ZHANG Yao1, 3. Quantitative Analysis of Water-Soluble Phosphorous Based on Raman
Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3871-3876. |
| [6] |
CHENG Hui-zhu1, 2, YANG Wan-qi1, 2, LI Fu-sheng1, 2*, MA Qian1, 2, ZHAO Yan-chun1, 2. Genetic Algorithm Optimized BP Neural Network for Quantitative
Analysis of Soil Heavy Metals in XRF[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3742-3746. |
| [7] |
XIE Peng, WANG Zheng-hai*, XIAO Bei, CAO Hai-ling, HUANG Yi, SU Wen-lin. Hyperspectral Quantitative Inversion of Soil Selenium Content Based on sCARS-PSO-SVM[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3599-3606. |
| [8] |
HUANG Zhao-di1, CHEN Zai-liang2, WANG Chen3, TIAN Peng2, ZHANG Hai-liang2, XIE Chao-yong2*, LIU Xue-mei4*. Comparing Different Multivariate Calibration Methods Analyses for Measurement of Soil Properties Using Visible and Short Wave-Near
Infrared Spectroscopy Combined With Machine Learning Algorithms[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3535-3540. |
| [9] |
AN Bai-song1, 2, WANG Xue-mei1, 2*, HUANG Xiao-yu1, 2, KAWUQIATI Bai-shan1, 2. Hyperspectral Estimation of Soil Lead Content Based on Random Frog Band Selection Algorithm[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(10): 3302-3309. |
| [10] |
DENG Yun1, 2, NIU Zhao-wen1, 2, FENG Qi-yao1, 2, WANG Yu1, 2*. A Novel Hyperspectral Prediction Model of Organic Matter in Red Soil Based on Improved Temporal Convolutional Network[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2942-2951. |
| [11] |
CAI Hai-hui1, ZHOU Ling2, SHI Zhou3, JI Wen-jun4, LUO De-fang1, PENG Jie1, FENG Chun-hui5*. Hyperspectral Inversion of Soil Organic Matter in Jujube Orchard
in Southern Xinjiang Using CARS-BPNN[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(08): 2568-2573. |
| [12] |
XIA Chen-zhen1, 2, 3, JIANG Yan-yan4, ZHANG Xing-yu1, 2, 3, SHA Ye5, CUI Shuai1, 2, 3, MI Guo-hua5, GAO Qiang1, 2, 3, ZHANG Yue1, 2, 3*. Estimation of Soil Organic Matter in Maize Field of Black Soil Area Based on UAV Hyperspectral Image[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(08): 2617-2626. |
| [13] |
ZHANG Zi-hao1, GUO Fei3, 4, WU Kun-ze1, YANG Xin-yu2, XU Zhen1*. Performance Evaluation of the Deep Forest 2021 (DF21) Model in
Retrieving Soil Cadmium Concentration Using Hyperspectral Data[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(08): 2638-2643. |
| [14] |
ZHANG Xia1, WANG Wei-hao1, 2*, SUN Wei-chao1, DING Song-tao1, 2, WANG Yi-bo1, 2. Soil Zn Content Inversion by Hyperspectral Remote Sensing Data and Considering Soil Types[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 2019-2026. |
| [15] |
HU Meng-ying1, 2, ZHANG Peng-peng1, 2, LIU Bin1, 2, DU Xue-miao1, 2, ZHANG Ling-huo1, 2, XU Jin-li1, 2*, BAI Jin-feng1, 2. Determination of Si, Al, Fe, K in Soil by High Pressure Pelletised Sample and Laser-Induced Breakdown Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(07): 2174-2180. |
|
|
|
|
