Sensitivity Improvement of P+Si/Au Thermopile-Based Gas Flow Sensor by Optimizing Heat-Sink and Thermal-Insulation Configuration

Shanshan Wang, Jiachou Wang, Xinxin Li
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引用次数: 2

Abstract

This paper reports a front-sided microfabricated high-sensitive p+Si/Au thermopile-based gas flow sensor for high-yield and low-cost volume production. Herein, the suspended p+Si beams, under the dielectric membrane and used to construct the p+Si/Au thermopile-based flow sensor, are only fabricated from one side of single crystal silicon wafer, without double-sided alignment exposure, cavity-SOI process, and wafer-bonding needed. The fabricated gas flow sensor with tiny-size of $0.5\text{mm}\times 0.7\text{mm}$ is achieved. Compared to the most of previously reported p+Si/metal thermopile-based flow sensor, by embedding the cold junction of p+Si beam into the silicon substrate and optimizing the thermal insulation of the suspended membrane from the silicon substrate, the fabricated flow sensor achieves higher sensitivity of 0.337mV/(SLM)/mW (Output without any amplification) for nitrogen gas flow and quick response time of 1.5ms.
通过优化散热器和隔热结构提高P+Si/Au热电堆气体流量传感器的灵敏度
本文报道了一种用于高产、低成本批量生产的前端微加工高灵敏度p+Si/Au热电堆气体流量传感器。本研究中,在介质膜下悬浮p+Si梁,用于构建基于p+Si/Au热电堆的流量传感器,仅从单晶硅片的一侧制作,不需要双面对准暴露、空腔- soi工艺和晶圆键合。实现了尺寸为0.5\text{mm} × 0.7\text{mm}$的微型气体流量传感器。与以往报道的大多数基于p+Si/金属热电堆的流量传感器相比,通过将p+Si梁的冷端嵌入到硅衬底中,并优化悬浮膜与硅衬底的绝热性,所制成的流量传感器对氮气流量的灵敏度达到0.37 mv /(SLM)/mW(无放大输出),响应时间达到1.5ms。
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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