Characterization of porous silicon based optical sensor system for biosensor applications

2009 IEEE Sensors Pub Date : 2009-10-01 DOI:10.1109/ICSENS.2009.5398128

A. Kovacs, P. Jonnalagadda, X. Meng, U. Mescheder

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引用次数: 7

Abstract

Porous silicon based multilayer structures for optical sensors have been simulated, fabricated and tested. The properties of optical sensors using porous silicon multilayer can be adjusted by appropriate substrate material, morphology, process parameters in the pore formation process and by surface treatment (thermal oxidation). Heavily and lightly doped p-doped substrates have been used to realize porous silicon layers with different morphology, porosity (30–80%), pore size (mesoporous range) and specific surface area (200–700m2/cm3). Thermal oxidation stabilizes the surface and results in hydrophilic surfaces for effective adsorption of liquid analytes. Oxidation reduces the porosity and the pore size but improves the wetting behavior of liquid analytes in the porous volume. Different multilayer structures using native and oxidized porous silicon and corresponding concepts of optical sensor systems have been proved for aqueous and organic analytes. Sensors using small pore size (2–4nm) and high porosity (70–80%) have been realized and characterized. A simple, low cost optical sensor system based on multilayer, a tunable light source and a detector has been realized.

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生物传感器应用中多孔硅基光学传感器系统的表征

多孔硅基多层光学传感器结构已经进行了模拟、制作和测试。多孔硅多层光学传感器的性能可以通过适当的衬底材料、形貌、成孔过程中的工艺参数和表面处理(热氧化)来调节。重掺杂和轻掺杂的p掺杂衬底已经被用来实现具有不同形貌、孔隙率(30-80%)、孔径(介孔范围)和比表面积(200-700m2 /cm3)的多孔硅层。热氧化使表面稳定，并产生亲水表面，以有效吸附液体分析物。氧化降低了孔隙度和孔径，但改善了液体分析物在多孔体积中的润湿行为。采用天然多孔硅和氧化多孔硅的不同多层结构以及相应的光学传感器系统概念已被证明用于水和有机分析物。小孔径(2-4nm)和高孔隙率(70-80%)的传感器已经实现并表征。实现了一种基于多层、可调光源和探测器的简单、低成本的光学传感器系统。

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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2009 IEEE Sensors

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