Development of a Broadband Terahertz WR-3 Waveguide Microcalorimeter in the 220~330 GHz

Wenze Yuan; Weidong Hu; Yuming Bai; Xiaohai Cui; Xiaomeng Liu; Jinwen Liu; Yong Li

doi:10.1109/TIM.2025.3554869

Development of a Broadband Terahertz WR-3 Waveguide Microcalorimeter in the 220~330 GHz

Wenze Yuan, Weidong Hu, Yuming Bai^*, Xiaohai Cui, Xiaomeng Liu, Jinwen Liu, Yong Li

^*Corresponding author for this work

School of Integrated Circuits and Electronics

Research output: Contribution to journal › Article › peer-review

Abstract

This article proposes a power sensor and a WR-3 waveguide microcalorimeter that can achieve traceable measurement of 220 ⁓ 330 -GHz terahertz wave power. The power sensor is based on a novel multilayer sensing chip with a smaller size and easier chip connection. The energy absorption of the terahertz power sensor could be more than 90%. The proposed WR-3 rectangular waveguide microcalorimeter has measurement stability and thermopile linearity. Subsequently, the measurement results of the proposed microcalorimeter are calibrated with mathematical derivation and practical experiments. It demonstrates that the proposed microcalorimeter could work well with an effective efficiency measurement uncertainty of 0.017⁓ 0.035 ( k =2 ) in the band of 220 ⁓ 330 GHz.

Original language	English
Article number	1007309
Journal	IEEE Transactions on Instrumentation and Measurement
Volume	74
DOIs	https://doi.org/10.1109/TIM.2025.3554869
Publication status	Published - 2025

Keywords

Microcalorimeter
power measurement
sensing chip
terahertz technology
WR-3

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10.1109/TIM.2025.3554869

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title = "Development of a Broadband Terahertz WR-3 Waveguide Microcalorimeter in the 220\textasciitilde{}330 GHz",

abstract = "This article proposes a power sensor and a WR-3 waveguide microcalorimeter that can achieve traceable measurement of 220 ⁓ 330 -GHz terahertz wave power. The power sensor is based on a novel multilayer sensing chip with a smaller size and easier chip connection. The energy absorption of the terahertz power sensor could be more than 90\%. The proposed WR-3 rectangular waveguide microcalorimeter has measurement stability and thermopile linearity. Subsequently, the measurement results of the proposed microcalorimeter are calibrated with mathematical derivation and practical experiments. It demonstrates that the proposed microcalorimeter could work well with an effective efficiency measurement uncertainty of 0.017⁓ 0.035 ( k =2 ) in the band of 220 ⁓ 330 GHz.",

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T1 - Development of a Broadband Terahertz WR-3 Waveguide Microcalorimeter in the 220~330 GHz

AU - Yuan, Wenze

AU - Hu, Weidong

AU - Bai, Yuming

AU - Cui, Xiaohai

AU - Liu, Xiaomeng

AU - Liu, Jinwen

AU - Li, Yong

PY - 2025

Y1 - 2025

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AB - This article proposes a power sensor and a WR-3 waveguide microcalorimeter that can achieve traceable measurement of 220 ⁓ 330 -GHz terahertz wave power. The power sensor is based on a novel multilayer sensing chip with a smaller size and easier chip connection. The energy absorption of the terahertz power sensor could be more than 90%. The proposed WR-3 rectangular waveguide microcalorimeter has measurement stability and thermopile linearity. Subsequently, the measurement results of the proposed microcalorimeter are calibrated with mathematical derivation and practical experiments. It demonstrates that the proposed microcalorimeter could work well with an effective efficiency measurement uncertainty of 0.017⁓ 0.035 ( k =2 ) in the band of 220 ⁓ 330 GHz.

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KW - power measurement

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Development of a Broadband Terahertz WR-3 Waveguide Microcalorimeter in the 220~330 GHz

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