多菌灵农药的激光拉曼光谱分析

doi:10.3964/j.issn.1000-0593(2014)06-1566-05

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摘要：实验采集多菌灵农药的固体和液体拉曼光谱信号，对固体的原始拉曼光谱信号进行小波去噪预处理，利用正交试验方法筛选小波去噪参数的最优组合。结果表明，采用db2小波基函数、分解层数为2、阈值方案选择为rigrsure、重调方式为sln时，去噪效果最好，信噪比为62.483。根据不同官能团的振动模式，对去噪后的拉曼光谱分3个波数段(1 400～2 000，700～1 400，200～700 cm^-1)进行谱峰归属和分析，得到了多菌灵农药分子在不同波数范围内的特征振动模式，其中，在619，725，964，1 022，1 265，1 274和1 478 cm^-1处的拉曼信号较强，可作为固体多菌灵农药的特征峰。从多菌灵农药的液体拉曼光谱中，找到了629，727，1 001，1 219，1 258和1 365 cm^-1特征峰，这些特征峰跟固体多菌灵农药的特征峰基本吻合。研究结果可为拉曼光谱分析技术在食品及农产品中农药残留的快速筛选提供判别依据。

关键词：激光拉曼光谱;多菌灵农药;小波去噪;谱峰归属

Abstract：Raman signal of solid and liquid carbendazim pesticide was collected by laser Raman spectrometer. The acquired Raman spectrum signal of solid carbendazim was preprocessed by wavelet analysis method, and the optimal combination of wavelet denoising parameter was selected through mixed orthogonal test. The results showed that the best effect was got with signal to noise ratio (SNR) being 62.483 when db2 wavelet function was used, decomposition level was 2, the threshold option scheme was ‘rigrsure’ and reset mode was ‘sln’. According to the vibration mode of different functional groups, the de-noised Raman bands could be divided into 3 areas: 1 400～2 000, 700～1 400 and 200～700 cm^-1. And the de-noised Raman bands were assigned with and analyzed. The characteristic vibrational modes were gained in different ranges of wavenumbers. Strong Raman signals were observed in the Raman spectrum at 619, 725, 964, 1 022, 1 265, 1 274 and 1 478 cm^-1, respectively. These characteristic vibrational modes are characteristic Raman peaks of solid carbendazim pesticide. Find characteristic Raman peaks at 629, 727, 1 001, 1 219, 1 258 and 1 365 cm^-1 in Raman spectrum signal of liquid carbendazim. These characteristic peaks were basically tallies with the solid carbendazim. The results can provide basis for the rapid screening of pesticide residue in food and agricultural products based on Raman spectrum.

Key words：Laser Raman spectrum;Carbendazim pesticide;Wavelet denoising;Spectrum peak assignment

收稿日期: 2013-07-31 修订日期: 2013-11-24

中图分类号:

O657.3

通讯作者: 吴瑞梅 E-mail: wuruimei036@163.com

引用本文:

王晓彬¹，吴瑞梅^{1, 2*}，刘木华¹，张庐陵¹，蔺磊¹，严霖元¹ . 多菌灵农药的激光拉曼光谱分析 [J]. 光谱学与光谱分析, 2014, 34(06): 1566-1570.
WANG Xiao-bin¹, WU Rui-mei^{1, 2*}, LIU Mu-hua¹, ZHANG Lu-ling¹, LIN Lei¹, YAN Lin-yuan¹ . Laser Raman Spectrum Analysis of Carbendazim Pesticide . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2014, 34(06): 1566-1570.

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[1] GAO Xing，YU Ji-cheng，GUO Nai-fei，et al(高兴，于基成，郭乃菲，等). Food and Machinery(食品与机械)，2010，26(6)：153.
[2] LAN Shan-shan，LIU Hong-cheng，LI Qi-wan，et al(兰珊珊，刘宏程，黎其万，等). Journal of Analytical Science(分析科学学报)，2011，27(02)：171.
[3] LI Fang，ZHANG Jing，YANG Zhong，et al(李芳，张静，杨中，等). Journal of Jilin Agricultural Sciences(吉林农业科学)，2013，38(03)：93.
[4] SUN Lu, CHEN Bin, GAO Rui-chang, et al(孙璐，陈斌，高瑞昌，等). Journal of Chinese Institute of Food Sci. and Tech.(中国食品学报)，2012，12(12)：113.
[5] Mohan S，Sundaraganesan N，Mink J. Spectrochimica Acta Part A: Molecular Spectroscopy，1991，47(8)：1111.
[6] Kim M S，Kim M K，Lee C J，et al. Bulletin of The Korean Chemical Society，2009，30(12)：2930.
[7] YANG Gui-jun，CHEN Yu-lun(杨桂君，陈玉伦). Chinese Journal of Spectroscopy Laboratory(光谱实验室)，2010，27(1)：325.
[8] CHEN Chen，XU Da-hai，CHENG Qing-hua(陈晨，徐大海，程庆华). Journal of Yangtze University(Nat Sci Edit)(长江大学学报·自科版)，2006，3(4)：31.
[9] XU Wei，ZHANG Shuai，WANG Ke-jia(徐伟，张帅，王克家). Applied Science and Technology(应用科技)，2009，36(11)：27.
[10] FANG Yong-hua，KONG Chao，LAN Tian-ge，et al(方勇华，孔超，兰天鸽，等). Optics and Precision Engineering(光学精密工程)，2006，14(6)：1089.
[11] CHEN Yong-jian，CEHN Rong，LI Yong-zeng，et al (陈永坚，陈荣，李永增，等). Spectroscopy and Spectral Analysis(光谱学与光谱分析)，2011，31(11)：2962.
[12] JIANG Yong, NI Yong-nian, ZHU Hui-fang(江勇，倪永年，朱惠芳). Journal of Nanchang University·Natural Science(南昌大学学报·理科版)，2012，36(4)：377.
[13] ZHOU Wei(周伟). Wavelet analysis and apply based on Matlab(基于Matlab的小波分析应用). Xi’an：Xidian University Press(西安电子科技大学出版社)，2010. 168.
[14] CHU Xiao-li(褚小立). Molecular Spectroscopy Analytical Technology Combined with Chemometrics and Its Applications(化学计量学方法与分子光谱分析技术). Beijing：Chemical Industry Press(北京：化学工业出版社)，2011.
[15] ZHU Zi-ying，GU Ren-ao，LU Tian-hong(朱自莹，顾仁敖，陆天虹). Raman Spectroscopy in Chemistry(拉曼光谱在化学中的应用). Shenyang：Northeastern University Press(沈阳：东北大学出版社)，1998.
[16] Venkateswaran C S，Pandya N S. Proceedings of the Indian Academy of Sciences-Section A，1942，15(5)：390.
[17] Unal A，Eren B. Spectrochimica Acta Part A：Molecular and Biomolecular Spectroscopy，2013，114：133.
[18] Dollish F R，Fateley W G，Bentley F F. Characteristic Raman Frequencies of Organic Compounds(有机化合物的特征拉曼频率). Translated by ZHU Zi-ying(朱自莹，译). Beijing：Chinese Chemical Society(北京：中国化学会)，1980.