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100-μm-Scale High-Detectivity Infrared Detector With Thermopile/Absorber Double-Deck Structure Formed in (111) Silicon | IEEE Journals & Magazine | IEEE Xplore

100-μm-Scale High-Detectivity Infrared Detector With Thermopile/Absorber Double-Deck Structure Formed in (111) Silicon


Abstract:

This article presents a 96 \mu \text{m}\,\,\times 106 \mu \text{m} sized single-crystalline silicon (SC-Si) /Au thermopile infrared (IR) detector, with the therm...Show More

Abstract:

This article presents a 96 \mu \text{m}\,\,\times 106 \mu \text{m} sized single-crystalline silicon (SC-Si) /Au thermopile infrared (IR) detector, with the thermopile and IR absorber located at different layers of a double-deck micromechanical structure for improving detectivity. In order to enhance IR-heat absorption within such a tiny device size, an umbrella-shaped SiN IR absorbing membrane instead of traditional plane IR-absorbing film occupies the whole area of the top layer structure. The umbrella-shaped IR absorber is suspended on top of the IR-detecting thermopile layer, with a central umbrella-stick to support the suspending and conducting the absorbed IR-heat to the bottom thermopile layer. The bottom thermopile layer consists of six pairs of spiral-shaped SC-Si/Au thermocouples that feature several times higher Seebeck coefficient compared to the traditional polysilicon/metal thermocouples. By combining surface-micromachining technique with a specific bulk-micromachining process performed in (111) silicon wafer, the double-deck structured IR-detector is successfully fabricated only from the front side of a single (111) silicon wafer for IC-foundry compatible low-cost manufacturing. Testing results show that this device of about 100- \mu \text{m} scale achieves an ultrahigh IR detectivity of 1.01 \times \,\,10^{{8}} cm \cdot Hz ^{{{1}/{2}}}\cdot \text{W}^{-{1}} , which is two times improvement compared to the recently reported thermopile IR detectors, though the counterparts had larger device area. Featuring tiny size and batch fabrication capability, the proposed high-performance IR-detector is promising in both single-point detection and multipixel arrayed temperature imaging applications.
Published in: IEEE Transactions on Electron Devices ( Volume: 68, Issue: 12, December 2021)
Page(s): 6233 - 6239
Date of Publication: 11 October 2021

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