Effects of cone angle and length of nanopores on the resistive pulse quality

电阻式触摸屏 脉搏(音乐) 纳米孔 Cone(正式语言) 质量(理念) 材料科学 光学 物理 纳米技术 计算机科学 电气工程 工程类 量子力学 探测器 算法
作者
Mostafa Bakouei,Seyedamirhosein Abdorahimzadeh,Mojtaba Taghipoor
出处
期刊:Physical Chemistry Chemical Physics [Royal Society of Chemistry]
卷期号:22 (43): 25306-25314 被引量:10
标识
DOI:10.1039/d0cp04728g
摘要

Resistive pulse sensing (RPS) has proved to be a viable method for the detection and characterization of micro and nano particles. Modern fabrication methods have introduced different nanopore geometries for resistive pulse sensors. In this paper, we have numerically studied the effects of membrane thickness and the pore's cone angle, as the main geometrical parameters, on the sensing performance of the nanopores used for nanoparticle detection in the resistive pulse sensing method. To compare the sensing performance, three resistive pulse quality parameters were investigated - sensitivity, pulse duration and pulse amplitude. The thorough investigation on the relations between the geometrical parameters and the pulse quality parameters produced several interesting results, which were categorized and summarized for different nanopore structures (as different nanopore platforms) enabling the readers to more effectively compare them with one another. The results revealed that large cone angle and low aspect ratio nanopores have higher pulse amplitude and sensitivity, but their low duration could be a challenge in the process of detecting the resistive pulse. In addition, our results show small variation in sensitivity and duration of large cone angle nanopores with respect to pore length change, which is explained using the effective length concept and the definition of electric field strength and length. The findings of the present work can be used in practical applications where choosing the optimal pore geometry is of crucial significance. Furthermore, the results provide several possible ways to improve the resistive pulse quality for better sensing performance.
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