王雪 (副教授)

副教授   硕士生导师

性别:男

毕业院校:中科院大连化学物理研究所

学位:博士

在职信息:在职

所在单位:盘锦校区海洋科学与技术学院

学科:环境科学

办公地点:大连理工大学海洋科学与技术学院D05-301

联系方式:wangxue@dlut.edu.cn

电子邮箱:wangxue@dlut.edu.cn

个人简介


王雪 博士/副教授/硕士生导师。本科毕业于浙江大学,博士毕业于中国科学院大学(中国科学院大连化学物理研究所),师从陈吉平研究员。一直从事环境污染物快速检测技术方面的研究工作。现为美国化学会(ACS)会员、中国化学会(CCS)会员、多个国际SCI期刊的审稿人;共发表SCI论文26篇、授权专利3项、主持科研项目4

研究生招生专业:环境科学与工程资源与环境

希望通过开发新型分析检测技术能够对环境中有毒有害污染物进行快速筛查和定量分析,主要研究内容包括:1)基于色谱、光谱和电化学的环境污染物分析检测技术;2)化学传感和生物传感技术的开发与应用;3)微塑料的分离和鉴定;

 

主持的科研项目:

[1] 国家自然科学基金青年基金项目,25万,2018.1-2020.12.

[2] 大连理工大学基本科研业务费交叉探索科研专题,10万,2018.1-2019.12

[3] 工业生态与环境工程教育部重点实验室开放课题,4万,2017.1 -2019.12

[4] 大连理工大学基本科研业务费人才引进专题,5万,2015.11-2017.12.

 

已发表论文如下:

[1] X. Wang*, Y. R. Shi, J. J. Shan, H. Zhou, M. J. Li, Electrochemical sensor for determination of bisphenol A based on MOF-reduced graphene oxide composites coupled with cetyltrimethylammonium bromide signal amplification, Ionics 26(6) (2020) 3135-3146.

[2] X. Wang*, M. J. Li, S. Yang, J. J. Shan, A novel electrochemical sensor based on TiO2-Ti3C2Tx/CTAB/chitosan composite for the detection of nitrite, Electrochimica Acta 359 (2020).

[3] J. J. Shan, Y. T. Zhang, J. Wang, T. Ren, M. K. Jin, X. Wang*, Microextraction based on microplastic followed by SERS for on-site detection of hydrophobic organic contaminants, an indicator of seawater pollution, Journal of Hazardous Materials 400 (2020).

[4] J. J. Shan, Y. T. Zhang, J. Liang, X. Wang*, Characterization of the Processing Conditions upon Textural Profile Analysis (TPA) Parameters of Processed Cheese Using Near-Infrared Hyperspectral Imaging, Analytical Letters 53(8) (2020) 1190-1203.

[5] J. J. Shan, J. Wang, J. J. Zhan, L. F. Liu, F. C. Wu, X. Wang*, Sorption behaviors of crude oil on polyethylene microplastics in seawater and digestive tract under simulated real-world conditions, Chemosphere 257 (2020).

[6] Y. T. Zhang, X. Wang, J. J. Shan*, J. B. Zhao, W. Zhang, L. F. Liu, F. C. Wu, Hyperspectral Imaging Based Method for Rapid Detection of Microplastics in the Intestinal Tracts of Fish, Environmental Science & Technology 53(9) (2019) 5151-5158.

[7] M. Wu, X. Wang*, J. J. Shan, H. Zhou, Y. R. Shi, M. J. Li, L. F. Liu, Sensitive and Selective Electrochemical Sensor Based on Molecularly Imprinted Polypyrrole Hybrid Nanocomposites for Tetrabromobisphenol A Detection, Analytical Letters 52(16) (2019) 2506-2523.

[8] X. Wang, J. J. Shan*, S. Q. Han, J. B. Zhao, Y. T. Zhang, Optimization of Fish Quality by Evaluation of Total Volatile Basic Nitrogen (TVB-N) and Texture Profile Analysis (TPA) by Near-Infrared (NIR) Hyperspectral Imaging, Analytical Letters 52(12) (2019) 1845-1859.

[9] X. Wang, M. Russel, Y. W. Zhang, J. B. Zhao, Y. T. Zhang, J. J. Shan*, A Clustering-Based Partial Least Squares Method for Improving the Freshness Prediction Model of Crucian Carps Fillets by Hyperspectral Image Technology, Food Analytical Methods 12(9) (2019) 1988-1997.

[10] J. J. Shan*, J. B. Zhao, Y. T. Zhang, L. F. Liu, F. C. Wu, X. Wang, Simple and rapid detection of microplastics in seawater using hyperspectral imaging technology, Analytica Chimica Acta 1050 (2019) 161-168.

[11] X. Wang*, M. J. Li, M. Wu, Y. R. Shi, J. J. Yang, J. J. Shan, L. F. Liu, Simultaneous Determination of Bisphenol A and Bisphenol S Using Multi-Walled Carbon Nanotubes Modified Electrode, International Journal of Electrochemical Science 13(12) (2018) 11906-11922.

[12] X. Wang*, J. Che, M. Wu, Y. R. Shi, M. J. Li, J. J. Shan, L. F. Liu, The Anti-Fouling Effect of Surfactants and Its Application for Electrochemical Detection of Bisphenol A, Journal of the Electrochemical Society 165(16) (2018) B814-B823.

[13] J. J. Shan*, J. B. Zhao, L. F. Liu, Y. T. Zhang, X. Wang, F. C. Wu, A novel way to rapidly monitor microplastics in soil by hyperspectral imaging technology and chemometrics, Environmental Pollution 238 (2018) 121-129.

[14] J. J. Shan*, X. Wang, H. Zhou, S. Q. Han, D. F. Al Riza, N. Kondo, Variable selection based on clustering analysis for improvement of polyphenols prediction in green tea using synchronous fluorescence spectra, Methods and Applications in Fluorescence 6(2) (2018) 8.

[15] J. J. Shan*, X. Wang, M. Russel, J. B. Zhao, Y. T. Zhang, Comparisons of Fish Morphology for Fresh and Frozen-Thawed Crucian Carp Quality Assessment by Hyperspectral Imaging Technology, Food Analytical Methods 11(6) (2018) 1701-1710.

[16] P. P. Qi, J. Wang, Z. W. Wang, X. Wang, X. Y. Wang, X. H. Xu, H. Xu, S. S. Di, H. Zhang, Q. Wang, X. Q. Wang*, Construction of a probe-immobilized molecularly imprinted electrochemical sensor with dual signal amplification of thiol graphene and gold nanoparticles for selective detection of tebuconazole in vegetable and fruit samples, Electrochimica Acta 274 (2018) 406-414.

[17] P. P. Qi, J. Wang, X. Wang, X. Y. Wang, Z. W. Wang, H. Xu, S. S. Di, Q. Wang, X. Q. Wang*, Sensitive determination of fenitrothion in water samples based on an electrochemical sensor layered reduced graphene oxide, molybdenum sulfide (MoS2)-Au and zirconia films, Electrochimica Acta 292 (2018) 667-675.

[18] H. Zhou*, L. Che, X. Y. Guo, X. Wang, J. J. Zhan, M. H. Wu, Y. F. Hu, X. L. Yi, X. W. Zhang, L. F. Liu, Interface modulation of bacteriogenic Ag/AgCl nanoparticles by boosting the catalytic activity for reduction reactions using Co2+ ions, Chemical Communications 53(36) (2017) 4946-4949.

[19] J. J. Shan*, X. Wang, M. Russel, J. B. Zhao, Rapid determination of flavonoids in green tea by synchronous fluorescence spectra coupled with chemometrics, Spectroscopy Letters 50(9) (2017) 501-506.

[20] J. J. Shan*, X. Wang, S. Q. Han, N. Kondo, Application of Curve Fitting and Wavelength Selection Methods for Determination of Chlorogenic Acid Concentration in Coffee Aqueous Solution by Vis/NIR Spectroscopy, Food Analytical Methods 10(4) (2017) 999-1006.

[21] X. B. Lu#,*, X. Wang#, L. D. Wu, L. X. Wu, Dhanjai, L. Fu, Y. Gao, J. P. Chen*, Response Characteristics of Bisphenols on a Metal-Organic Framework-Based Tyrosinase Nanosensor, Acs Applied Materials & Interfaces 8(25) (2016) 16533-16539.

[22] L. D. Wu#, X. B. Lu#,*, X. Wang, Y. Song, J. P. Chen*, An electrochemical deoxyribonucleic acid biosensor for rapid genotoxicity screening of chemicals, Analytical Methods 7(8) (2015) 3347-3352.

[23] X. Wang, X. B. Lu*, L. D. Wu, J. P. Chen*, 3D metal-organic framework as highly efficient biosensing platform for ultrasensitive and rapid detection of bisphenol A, Biosensors & Bioelectronics 65 (2015) 295-301.

[24] X. Wang#, X. B. Lu#,*, L. D. Wu, J. P. Chen, Direct Electrochemical Tyrosinase Biosensor based on Mesoporous Carbon and Co3O4 Nanorods for the Rapid Detection of Phenolic Pollutants, Chemelectrochem 1(4) (2014) 808-816.

[25] X. Wang, X. B. Lu, J. P. Chen*, Development of biosensor technologies for analysis of environmental contaminants, Trends in Environmental Analytical Chemistry 2 (2014) 25-32.

[26] X. B. Lu*, X. Wang, J. Jin, Q. Zhang, J. P. Chen*, Electrochemical biosensing platform based on amino acid ionic liquid functionalized graphene for ultrasensitive biosensing applications, Biosensors & Bioelectronics 62 (2014) 134-139.

 

授权专利:

[1] 王雪卢宪波;陈吉平;一种酪氨酸酶电化学生物传感器及其应用;CN201310239818.4

[2] 卢宪波;王雪;陈吉平;一种制备水相可分散的导电石墨烯分散浆液或固体的方法;CN201410213914.6

[3] 张议文;杜文强;吴明火;邓付美;王雪;刘广群;柳丽芬;一种分子印迹固相萃取-液质联用检测膝沟藻毒素的分析方法;CN201610801161.X