基于马钱子孢子铁涂层叶片的微尺度湿度传感器

Biosensors Pub Date : 2024-08-26 DOI:10.3390/bios14090414
Yanting Liu, Zhexuan Lin, Xiaochun Li, Rui Huang, Xuewan Wu, Ruyi Deng, Kaisong Yuan
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引用次数: 0

摘要

湿度传感器深深影响着人类的生产制造和日常生活,而研究人员一般都专注于开发具有更高的稳定性、更高的线性度和快速响应时间等特性的湿度传感器。然而,很少有人讨论通过将传感器尺寸微型化到微尺度来测量微环境中的湿度,而现有的湿度传感器很难达到微尺度。因此,本研究提出了一种测量微尺度相对湿度的方法,即利用马钱子孢子在 50% 至 90% 相对湿度范围内的独特形态进行测量。马钱子孢子对环境相对湿度的变化反应灵敏,即使在铁溅射后仍能保持其原始活性,从而赋予传感器磁性。在首次应用中,我们利用这种微型传感器在微流控芯片或细胞迁移微芯片的通道中工作,作为在微环境中工作的一个实例。我们还使用 COMSOL Multiphysics 6.2 软件来模拟微通道中相对湿度的变化。其次,这种微尺度传感器与基于智能手机的显微镜相结合,测量皮肤的湿度。这些微尺度传感器为在微环境中感知湿度铺平了新的道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Microscale Humidity Sensor Based on Iron-Coated Elaters of Equisetum Spores
Humidity sensors deeply influence human manufacturing production and daily life, while researchers generally focus on developing humidity sensors with higher stability, higher linearity, rapid response time, etc. Yet, few people discuss measuring humidity in the microenvironment by miniaturizing sensor size into a microscale, in which the existing humidity sensors are difficult to reach. Accordingly, this study proposes a methodology for measuring relative humidity in the microscale by utilizing the distinctive morphologies of Equisetum spores across a range of relative humidities between 50% and 90%. Equisetum spores are responsive to changes in ambient relative humidity and remain in their original activities even after iron sputtering, which aims to endow the sensor with magnetic properties. The test performed in this study demonstrated a response time of 3.3 s and a recovery time of 3.6 s. In the first application, we employed such microscale sensors to work in the channel of the microfluidic chip or the cell migration microchip, as an example of working in the microenvironment. COMSOL Multiphysics 6.2 software was also used to simulate the change in relative humidity in such microchannels. Secondly, such microscale sensors are combined with smartphone-based microscopy to measure the humidity of the skin. These microscale sensors pave the new way to sensing humidity in microenvironments.
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