Influence of One-Dimensional Photonic Crystal on Raman Signal Enhancement: A Detailed Experimental Study.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Maria Krajačić, Nikola Baran, Ana Tolić, Lara Mikac, Mile Ivanda, Ozren Gamulin, Marko Škrabić
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引用次数: 0

Abstract

The enhancement of Raman signals using photonic crystal structures has been the subject of numerous experimental and theoretical studies, leading to a variety of issues and inconsistencies. This paper presents a comprehensive experimental investigation into the impact of alignment between the laser excitation wavelength and the specific position of the photonic band gap on signal enhancement in Raman spectroscopy. By employing one-dimensional (1D) porous silicon photonic crystals, a systematic analysis across a large number of spectra was conducted. The study focused on examining the signal enhancement of both the Raman ∼520 cm-1 silicon band, representing the constituent material of photonic crystal, and the most prominent Raman bands of crystal violet, used as a probe molecule. The probe molecules were both infiltrated into and adsorbed on top of the photonic crystal structure. The obtained experimental results for the contribution of 1D photonic crystals to Raman signal enhancement are much smaller compared to most predictions. The Raman signal of silicon and the signal from the probe molecule are enhanced ≤2.5 times when the laser excitation aligns with the edge of the photonic band gap, strictly defined as the position at the very bottom of the reflectance peak. The results have been discussed within the context of theoretical explanations.

一维光子晶体对拉曼信号增强的影响:详细实验研究
利用光子晶体结构增强拉曼信号一直是众多实验和理论研究的主题,导致了各种问题和矛盾。本文对激光激发波长与光子带隙特定位置之间的排列对拉曼光谱信号增强的影响进行了全面的实验研究。通过采用一维(1D)多孔硅光子晶体,对大量光谱进行了系统分析。研究重点考察了代表光子晶体组成材料的硅∼520 cm-1 拉曼光谱带和作为探针分子的水晶紫最突出的拉曼光谱带的信号增强情况。探针分子既渗入到光子晶体结构中,也吸附在光子晶体结构的顶部。实验结果表明,一维光子晶体对拉曼信号增强的贡献比大多数预测要小得多。当激光激发对准光子带隙边缘(严格定义为反射峰最底部的位置)时,硅的拉曼信号和探针分子的信号增强≤2.5 倍。这些结果已根据理论解释进行了讨论。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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