SPR-Amplified TiO2−NanoMXene Heterojunction for Ultrasensitive Contactless Human Activity Recognition

Yan Wang; Chong Li; Shiya Qi; Xinghong Chen; Jian Yang; Ziqian Chen; Xueming Hong; Jingting Luo; Yongqing Fu; Jinghan Zhang; Xuejin Li; Ran Tao; Yuzhi Chen

doi:10.1021/acs.analchem.5c07662

SPR-Amplified TiO2−NanoMXene Heterojunction for Ultrasensitive Contactless Human Activity Recognition

Yan Wang, Chong Li, Shiya Qi, Xinghong Chen, Jian Yang, Ziqian Chen, Xueming Hong, Jingting Luo, Yongqing Fu, Jinghan Zhang, Xuejin Li, Ran Tao^*, Yuzhi Chen^*

^*Corresponding author for this work

School of Engineering Physics and Mathematics

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

Abstract

Contactless human activity recognition (HAR) is a cornerstone of next-generation intelligent systems, but vision/inertial sensor-based progress is limited by reliability and privacy concerns. Monitoring subtle moisture signatures offers a smart alternative, yet constrained by either sensitive material or sensor architecture design and facing the trade-off among ultrasensitivity, rapid response, and scalable multichannel operation. We address this via a new moisture-sensing paradigm: a plasmon-amplified TiO2–nanoMXene heterojunction integrated onto a fiber-optic tip, leveraging light as an active catalyst in a self-reinforcing feedback loop. Surface plasmon resonance (SPR) injects hot electrons, amplifying the built-in electric field of the heterojunction to enhance H2O polarization and boost the trace moisture adsorption. This alters dielectric constant, feeding back to SPR signals. This self-reinforcing cycle translates subtle moisture signatures into a robust optical output, enabling a new class of HAR with ultrahigh sensitivity, fast response/recovery, minimal hysteresis, and robust environmental resilience. Its transformative potential is validated through contactless finger sensing, noninvasive diaper wetness monitoring, and clinical-grade respiratory analysis.

Original language	English
Pages (from-to)	8404–8412
Number of pages	9
Journal	Analytical Chemistry
Volume	98
Issue number	11
Early online date	9 Mar 2026
DOIs	https://doi.org/10.1021/acs.analchem.5c07662
Publication status	Published - 24 Mar 2026

Keywords

SPR amplification
TiO2-nanoMXene heterojunction
moisture sensing
human activity recognition

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10.1021/acs.analchem.5c07662

Analytical Chemistry final ManuscriptAccepted author manuscript, 1.68 MBLicence: CC BY

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title = "SPR-Amplified TiO2−NanoMXene Heterojunction for Ultrasensitive Contactless Human Activity Recognition",

abstract = "Contactless human activity recognition (HAR) is a cornerstone of next-generation intelligent systems, but vision/inertial sensor-based progress is limited by reliability and privacy concerns. Monitoring subtle moisture signatures offers a smart alternative, yet constrained by either sensitive material or sensor architecture design and facing the trade-off among ultrasensitivity, rapid response, and scalable multichannel operation. We address this via a new moisture-sensing paradigm: a plasmon-amplified TiO2–nanoMXene heterojunction integrated onto a fiber-optic tip, leveraging light as an active catalyst in a self-reinforcing feedback loop. Surface plasmon resonance (SPR) injects hot electrons, amplifying the built-in electric field of the heterojunction to enhance H2O polarization and boost the trace moisture adsorption. This alters dielectric constant, feeding back to SPR signals. This self-reinforcing cycle translates subtle moisture signatures into a robust optical output, enabling a new class of HAR with ultrahigh sensitivity, fast response/recovery, minimal hysteresis, and robust environmental resilience. Its transformative potential is validated through contactless finger sensing, noninvasive diaper wetness monitoring, and clinical-grade respiratory analysis.",

keywords = "SPR amplification, TiO2-nanoMXene heterojunction, moisture sensing, human activity recognition",

author = "Yan Wang and Chong Li and Shiya Qi and Xinghong Chen and Jian Yang and Ziqian Chen and Xueming Hong and Jingting Luo and Yongqing Fu and Jinghan Zhang and Xuejin Li and Ran Tao and Yuzhi Chen",

year = "2026",

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doi = "10.1021/acs.analchem.5c07662",

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T1 - SPR-Amplified TiO2−NanoMXene Heterojunction for Ultrasensitive Contactless Human Activity Recognition

AU - Wang, Yan

AU - Li, Chong

AU - Qi, Shiya

AU - Chen, Xinghong

AU - Yang, Jian

AU - Chen, Ziqian

AU - Hong, Xueming

AU - Luo, Jingting

AU - Fu, Yongqing

AU - Zhang, Jinghan

AU - Li, Xuejin

AU - Tao, Ran

AU - Chen, Yuzhi

PY - 2026/3/24

Y1 - 2026/3/24

N2 - Contactless human activity recognition (HAR) is a cornerstone of next-generation intelligent systems, but vision/inertial sensor-based progress is limited by reliability and privacy concerns. Monitoring subtle moisture signatures offers a smart alternative, yet constrained by either sensitive material or sensor architecture design and facing the trade-off among ultrasensitivity, rapid response, and scalable multichannel operation. We address this via a new moisture-sensing paradigm: a plasmon-amplified TiO2–nanoMXene heterojunction integrated onto a fiber-optic tip, leveraging light as an active catalyst in a self-reinforcing feedback loop. Surface plasmon resonance (SPR) injects hot electrons, amplifying the built-in electric field of the heterojunction to enhance H2O polarization and boost the trace moisture adsorption. This alters dielectric constant, feeding back to SPR signals. This self-reinforcing cycle translates subtle moisture signatures into a robust optical output, enabling a new class of HAR with ultrahigh sensitivity, fast response/recovery, minimal hysteresis, and robust environmental resilience. Its transformative potential is validated through contactless finger sensing, noninvasive diaper wetness monitoring, and clinical-grade respiratory analysis.

AB - Contactless human activity recognition (HAR) is a cornerstone of next-generation intelligent systems, but vision/inertial sensor-based progress is limited by reliability and privacy concerns. Monitoring subtle moisture signatures offers a smart alternative, yet constrained by either sensitive material or sensor architecture design and facing the trade-off among ultrasensitivity, rapid response, and scalable multichannel operation. We address this via a new moisture-sensing paradigm: a plasmon-amplified TiO2–nanoMXene heterojunction integrated onto a fiber-optic tip, leveraging light as an active catalyst in a self-reinforcing feedback loop. Surface plasmon resonance (SPR) injects hot electrons, amplifying the built-in electric field of the heterojunction to enhance H2O polarization and boost the trace moisture adsorption. This alters dielectric constant, feeding back to SPR signals. This self-reinforcing cycle translates subtle moisture signatures into a robust optical output, enabling a new class of HAR with ultrahigh sensitivity, fast response/recovery, minimal hysteresis, and robust environmental resilience. Its transformative potential is validated through contactless finger sensing, noninvasive diaper wetness monitoring, and clinical-grade respiratory analysis.

KW - SPR amplification

KW - TiO2-nanoMXene heterojunction

KW - moisture sensing

KW - human activity recognition

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DO - 10.1021/acs.analchem.5c07662

M3 - Article

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JO - Analytical Chemistry

JF - Analytical Chemistry

IS - 11

ER -

SPR-Amplified TiO2−NanoMXene Heterojunction for Ultrasensitive Contactless Human Activity Recognition

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Keywords

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