表面增强拉曼光谱对纺织品文物中茜素和茜紫素的快速检测

doi:10.13475/j.fzxb.20180305807

纺织学报 ›› 2019, Vol. 40 ›› Issue (03): 76-82.doi: 10.13475/j.fzxb.20180305807

表面增强拉曼光谱对纺织品文物中茜素和茜紫素的快速检测

陈磊¹, 裴克梅¹, 康晓静², 李文瑛², 赵丰³, 刘剑³()

1.浙江理工大学化学系, 浙江杭州 310018
2.新疆文物考古研究所, 新疆乌鲁木齐 830011
3.中国丝绸博物馆, 浙江杭州 310002

收稿日期:2018-03-23 修回日期:2018-12-13 出版日期:2019-03-15 发布日期:2019-03-15
通讯作者: 刘剑
作者简介:陈磊(1992—),男,硕士生。主要研究方向为用表面增强拉曼光谱技术检测分析古代纺织品染料。
基金资助:
国家自然科学基金资助项目(21673208);浙江省文物保护科技项目(2017002);浙江省自然科学基金资助项目(LY16B070009)

Rapidly detection of alizarin and purpurin in textile relics by surface-enhanced Raman spectroscopy

CHEN Lei¹, PEI Kemei¹, KANG Xiaojing², LI Wenying², ZHAO Feng³, LIU Jian³()

1. Department of Chemistry, Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
2. Xinjiang Institute of Relics and Archaeology, Urumqi, Xinjiang 830011, China
3. China National Silk Museum, Hangzhou, Zhejiang 310002, China

Received:2018-03-23 Revised:2018-12-13 Online:2019-03-15 Published:2019-03-15
Contact: LIU Jian

摘要/Abstract

摘要：

为快速检测古代纺织品文物中的天然色素并达到无损分析的目的,采用表面增强拉曼光谱技术(SERS)对纺织品文物中天然染料茜素和茜紫素进行鉴定。以纳米银溶胶为SERS基底检测茜素和茜紫素的标准品,利用密度泛函理论计算结果对茜素和茜紫素分子的SERS光谱进行确认,分析得到茜素和茜紫素的SERS光谱在3种激发波长下的差异,并找出判断茜素和茜紫素存在的特征峰。在此基础上,从纺织品文物中提取1根长度约为2 mm的纤维,采用原位非萃取水解方法对其进行预处理,并进行SERS检测。结果表明,出土于新疆营盘的纺织品文物中红色染料成分是茜素和茜紫素。

关键词: 表面增强拉曼光谱, 茜素, 茜紫素, 纺织品文物, 密度泛函理论

Abstract:

In order to quickly detect natural pigments in ancient relics and achieve non-destructive analysis, surface-enhanced Raman spectroscopy(SERS) was adopted to rapidly identify natural dyes of alizarin and purpurin in textile relic samples. Silver colliod was adopted a substrate to detect alizarin and purpurin standard. The SERS spectra of alizarin and purpurin were identified detailed by the density functional theory. The difference of SERS spectra of alizarin and purpurin at three excitation wavelengths was analyzed, and the characteristic peaks for judging the presence of alizarin and purpurin were found. Based on the SERS of alizarin and purpurin standard, extracting a fiber about 2 mm long in the textile relics. After pretreatment of cultural fiber by in situ non-extraction hydrolysis method, SERS technology was used for the detection. The results shows that the red dye components in the textile relics which are unearthed in Xinjiang's Yingpan plate are alizarin and purpurin.

Key words: surface-enhanced Raman spectroscopy, alizarin, purpurin, textile relic, density function theory

中图分类号:

O652.1

陈磊, 裴克梅, 康晓静, 李文瑛, 赵丰, 刘剑. 表面增强拉曼光谱对纺织品文物中茜素和茜紫素的快速检测[J]. 纺织学报, 2019, 40(03): 76-82.

CHEN Lei, PEI Kemei, KANG Xiaojing, LI Wenying, ZHAO Feng, LIU Jian. Rapidly detection of alizarin and purpurin in textile relics by surface-enhanced Raman spectroscopy[J]. Journal of Textile Research, 2019, 40(03): 76-82.

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参考文献 17

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序号	拉曼位移实验值/cm^-1	振动模式	拉曼位移计算值/cm^-1
V₁	343(w)	面外弯曲振动C₁₉C₇C₉C₈[24%],面外弯曲振动O₂₅C₁₁C₂₁C₂₄[30%]	340
V₂	479(w)	弯曲振动C₈C₉C₁₁[20%], 弯曲振动C₂₄C₂₁C₇[23%]	476
V₃	581(vw)	弯曲振动O₂₂C₂₁C₂₄[14%], 弯曲振动C₄C₅C₆[26%]	585
V₄	633(vw)	弯曲振动C₉C₁₁C₂₄[14%] ,弯曲振动O₂₅C₂₄C₁₁[15%]	624
V₅	662(vw)	弯曲振动C₄C₅C₆[13%],弯曲振动C₁C₅C₆[20%]	674
V₆	681(sh)	扭绞振动C₃C₂C₁C₆[11%],面外弯曲振动O₁₅C₁₁C₂₁C₂₄[14%]	676
V₇	819(w)	扭绞振动H₁₂C₁C₆C₅[17%], 面外弯曲振动O₁₈C₄C₇C₁₇[17%]	812
V₈	900(w)	弯曲振动C₁C₆C₅[13%], 弯曲振动O₂₀C₁₉C₈[18%]	909
V₉	1 016(m)	扭绞振动H₁₅C₆C₅C₄[23%], 扭绞振动H₁₂C₁C₆C₅[28%]	1 015
V₁₀	1 049(m )	伸缩振动C₁₉C₈[13%], 伸缩振动C₁C₆[15%]	1 037
V₁₁	1 161(m)	伸缩振动C₉C₁₁[17%], 弯曲振动H₁₆C₁₁C₉[21%]	1 179
V₁₂	1 189(w)	弯曲振动H₁₂C₁C₆[12%],弯曲振动H₁₃C₂C₁[29%]	1 192
V₁₃	1 206(w)	伸缩振动C₇C₁₇[10%], 弯曲振动H₁₀C₉C₁₁[15%]	1 216
V₁₄	1 291(s )	弯曲振动H₁₃C₂C₁[11%],弯曲振动H₁₄C₅C₆[18%]	1 298
V₁₅	1 324(s)	伸缩振动C₂C₁[12%],伸缩振动C₁₉C₈[26%]	1 324
V₁₆	1 419(s)	伸缩振动C₂₁C₇[10%], 弯曲振动H₂₃O₂₂C₂₁[34%]	1 399
V₁₇	1 457(w)	伸缩振动C₈C₉[24%], 弯曲振动H₂₆O₂₅C₂₄[35%]	1 459
V₁₈	1 552(w )	伸缩振动O₁₈C₁₇[14%], 弯曲振动H₁₀C₉C₁₁[16%]	1 530
V₁₉	1 601(w)	弯曲振动C₃C₂C₁[15%],伸缩振动C₁C₆[29%]	1 627

序号	拉曼位移实验值/cm^-1	振动模式	拉曼位移计算值/cm^-1
V₁	423(w)	弯曲振动C₇C₁₆C₄[12%], 弯曲振动O₂₆C₉C₁₀[20%]	423
V₂	452(w)	弯曲振动C₂₃C₂₀C₇[24%], 弯曲振动C₈C₉C₁₀[27%]	457
V₃	609(m)	弯曲振动C₄C₅C₆[13%], 弯曲振动C₉C₁₀C₂₃[19%]	607
V₄	650(m)	扭绞振动H₁₅C₁₀C₂₃C₂₀[10%],面外弯曲振动O₂₆C₈C₁₀C₉[38%]	644
V₅	905(w)	弯曲振动C₁₈C₈C₉[11%],弯曲振动O₁₉C₁₈C₈[17%]	914
V₆	970(s)	伸缩振动C₁₈C₈[11%], 伸缩振动C₈C₉[13%]	986
V₇	1 064(m)	伸缩振动C₆C₅[16%], 伸缩振动C₁C₆[32%]	1 057
V₈	1 154(m)	弯曲振动H₁₃C₅C₆[10%],伸缩振动C₉C₁₀[10%]	1 177
V₉	1 211(m)	伸缩振动O₂₆C₉[13%],弯曲振动H₁₅C₁₀C₂₃[46%]	1 219
V₁₀	1 290(s )	伸缩振动C₁₆C₄[13%]	1 291
V₁₁	1 321(s)	弯曲振动H₂₅O₂₄C₂₃[13%]	1 317
V₁₂	1 391(s,br)	伸缩振动C₁₆C₄[12%], 伸缩振动C₇C₁₆[13%]	1 393
V₁₃	1 471(m)	弯曲振动H₁₁C₁C₆[10%],弯曲振动H₁₄C₆C₅[11%]	1 499

表面增强拉曼光谱对纺织品文物中茜素和茜紫素的快速检测

Rapidly detection of alizarin and purpurin in textile relics by surface-enhanced Raman spectroscopy

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