Noise in nanopore sensors: Sources, models, reduction, and benchmarking

IF 2.7

Nanotechnology and Precision Engineering Pub Date : 2020-03-01 DOI:10.1016/j.npe.2019.12.008

Shengfa Liang , Feibin Xiang , Zifan Tang , Reza Nouri , Xiaodong He , Ming Dong , Weihua Guan

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引用次数: 31

Abstract

Label-free nanopore sensors have emerged as a new generation technology of DNA sequencing and have been widely used for single molecule analysis. Since the first α-hemolysin biological nanopore, various types of nanopores made of different materials have been under extensive development. Noise represents a common challenge among all types of nanopore sensors. The nanopore noise can be decomposed into four components in the frequency domain (1/f noise, white noise, dielectric noise, and amplifier noise). In this work, we reviewed and summarized the physical models, origins, and reduction methods for each of these noise components. For the first time, we quantitatively benchmarked the root mean square (RMS) noise levels for different types of nanopores, demonstrating a clear material-dependent RMS noise. We anticipate this review article will enhance the understanding of nanopore sensor noises and provide an informative tutorial for developing future nanopore sensors with a high signal-to-noise ratio.

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纳米孔传感器中的噪声:来源、模型、减少和基准测试

无标记纳米孔传感器是新一代DNA测序技术，已广泛应用于单分子分析。自第一个α-溶血素生物纳米孔出现以来，不同材料制成的各种类型的纳米孔得到了广泛的发展。噪声是所有类型的纳米孔传感器面临的共同挑战。纳米孔噪声在频域上可分解为4个分量(1/f噪声、白噪声、介电噪声和放大器噪声)。在这项工作中，我们回顾和总结了这些噪声成分的物理模型、来源和减少方法。我们首次对不同类型纳米孔的均方根(RMS)噪声水平进行了定量基准测试，证明了明显的材料依赖性RMS噪声。希望本文能加深对纳米孔传感器噪声的认识，为今后研制高信噪比纳米孔传感器提供参考。

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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Nanotechnology and Precision Engineering

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