Development of nanocrystallized magnetoelastic sensors with self-biased effect and improved mass sensitivity

IF 6.5 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Sensors and Actuators Reports Pub Date : 2024-10-11 DOI:10.1016/j.snr.2024.100251

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引用次数: 0

Abstract

The growing demand for cost-effective and wireless sensing technologies requires the development of simple, efficient and optimized sensors able to accurately detecting external agents. Magnetoelastic resonators represent an alternative to the traditional sensing systems, able to combine all the previously cited factors. Several studies have focused on increasing their sensitivity, in order to make it closer to the market. The present study explores thermal treatments as a novel approach to enhance the sensitivity of magnetoelastic resonators, focusing on the positive impact of crystallization processes induced in magnetoelastic platforms. The experimental results confirm an enhancement of resonant frequency and quality factor of the magnetoelastic platforms as treatment temperature increases. Particularly, the sensor annealed at 550 °C shows an increase of the resonant frequency value of 45 % with respect to the as-quenched platform, being that increase of around 1700 % for the quality factor. In addition, the nanocrystallization induction leads to a self-biased resonance, consequence of the intrinsic magnetization resulting from the crystallization in Fe₂B and FeCo phases. Further, the study shows the importance of stability in resonant frequency, emphasizing the potential of the 550 °C-annealed platform for mass sensor applications. Gold deposition experiments reveal the enhanced sensitivity of the sensor annealed at 550 °C of 40 % compared to the as-quenched sensor, as well as an increase of 38 % on its accuracy. These findings represent a significant step forward in the development of magnetoelastic-based mass sensors, highlighting the pivotal role of thermal treatments in optimizing sensitivity for practical and efficient external agents detection systems.

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开发具有自偏压效应和更高质量灵敏度的纳米结晶磁弹性传感器

对经济高效的无线传感技术的需求日益增长，这就要求开发简单、高效和优化的传感器，以准确探测外部物质。磁弹性谐振器是传统传感系统的替代品，能够将前面提到的所有因素结合起来。有几项研究侧重于提高其灵敏度，以使其更接近市场。本研究探讨了热处理作为提高磁弹性谐振器灵敏度的一种新方法，重点是磁弹性平台结晶过程的积极影响。实验结果证实，随着处理温度的升高，磁弹性平台的谐振频率和品质因数都会提高。特别是在 550 °C 下退火的传感器，其谐振频率值比淬火后的平台提高了 45%，品质因数提高了约 1700%。此外，纳米结晶诱导导致了自偏置共振，这是 Fe2B 和 FeCo 相结晶产生的固有磁化的结果。此外，研究还显示了谐振频率稳定性的重要性，强调了 550 °C 退火平台在质量传感器应用方面的潜力。金沉积实验表明，与淬火传感器相比，550 ℃ 退火传感器的灵敏度提高了 40%，精度提高了 38%。这些发现标志着基于磁弹性的质量传感器的开发向前迈出了重要一步，突出了热处理在优化实用高效的外部介质检测系统灵敏度方面的关键作用。

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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来源期刊

Sensors and Actuators Reports Multiple-

CiteScore

9.60

自引率

0.00%

发文量

审稿时长

49 days

期刊介绍： Sensors and Actuators Reports is a peer-reviewed open access journal launched out from the Sensors and Actuators journal family. Sensors and Actuators Reports is dedicated to publishing new and original works in the field of all type of sensors and actuators, including bio-, chemical-, physical-, and nano- sensors and actuators, which demonstrates significant progress beyond the current state of the art. The journal regularly publishes original research papers, reviews, and short communications. For research papers and short communications, the journal aims to publish the new and original work supported by experimental results and as such purely theoretical works are not accepted.