Synthesis of Silver Nanoplates With a Narrow LSPR Band for Chemical Sensing Through a Plasmon-Mediated Process Using Photochemical Seeds

AMI: Acta Materialia Pub Date : 2021-11-01 DOI:10.2139/ssrn.3910604

Chien-Chia Huang, Hong-Jun Chen, Qi Lun Leong, Wai-Kit Lai, C. Hsu, Jui-Chang Chen, Cheng-Liang Huang

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引用次数: 7

Abstract

The plasmon-mediated process is one of the most common and well-studied methods to synthesize silver nanoplates (AgNPts). In a typical plasmon-mediated process, silver seeds are generated by chemical reduction using NaBH4 (abbreviated as CR seeds) before the plasmon-mediated process. However, a broad localized surface plasmon resonance (LSPR) band of AgNPts (usually broader than 150 nm) synthesized using the typical plasmon-mediated process would possibly limit their further applications. In this study, silver seeds are generated using a photochemical reduction method (abbreviated as PCR seeds). These PCR seeds then convert to AgNPts with irradiation by green LEDs or by a sodium lamp through the plasmon-mediated process. Furthermore, a very narrow LSPR bandwidth (approximately 67 nm) can be obtained when these AgNPts are further irradiated with red LEDs. Due to high refractive index sensitivity and sharp LSPR bandwidth, the as-prepared AgNPts have a high figure of merit (FOM) and can be used for spectroscopic chemical sensing applications. The silver seeds generated by this photochemical method can provide another choice for the plasmon-mediated process to synthesize AgNPts with high optical quality.

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光化学种子等离子体介导合成具有窄LSPR带的银纳米片

等离子体介导的过程是合成银纳米片最常见和研究最多的方法之一。在典型的等离子体介导过程中，银种子是在等离子体介导过程之前用NaBH4化学还原生成的(简称CR种子)。然而，使用典型的等离子体介导工艺合成agnpt的宽局部表面等离子体共振(LSPR)带(通常宽于150 nm)可能会限制其进一步应用。本研究采用光化学还原法生成银种子(简称PCR种子)。这些PCR种子在绿色led或钠灯照射下通过等离子体介导的过程转化为agnpt。此外，当这些agnpt进一步用红色led照射时，可以获得非常窄的LSPR带宽(约67 nm)。由于高折射率灵敏度和锐利的LSPR带宽，制备的agnpt具有高品质系数(FOM)，可用于光谱化学传感应用。这种光化学方法产生的银种子为等离子体介导合成高光学质量的agnpt提供了另一种选择。

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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AMI: Acta Materialia

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