A Self-Powered Tactile Sensor Resistant to Environmental Interference

Hao Suo; Li Li; Jie Sun; Yu Zhang; Bo Zhao; Xian Zheng; Yu Wang; Guodong Zhang; Zhijun Wang; Panlai Li; Daqing Yang; Xin Zhang; Feng Wang

doi:10.1002/adma.202516596

A Self-Powered Tactile Sensor Resistant to Environmental Interference

Hao Suo^* (Co-first Author), Li Li (Co-first Author), Jie Sun, Yu Zhang, Bo Zhao, Xian Zheng, Yu Wang, Guodong Zhang, Zhijun Wang, Panlai Li, Daqing Yang, Xin Zhang^*, Feng Wang^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

4 Citations (Scopus)

Abstract

Developing advanced tactile sensors is important for cutting-edge applications such as human-machine interaction. However, the current tactile sensing technology primarily exploits triboelectrification, which is inherently susceptible to ambient interference, obstructing their real-world applications. Herein, a robust tactile sensing platform is presented that leverages piezoelectrics for mechano-optoelectronic transduction. A new class of ScBO₃:Cr³⁺ crystals is developed that can produce intense broadband near-infrared light under sole mechanical pressure through self-recoverable mechanoluminescence (ML). Through a combinatorial doping strategy, deliberate modulation of ML profile is achieved across a broad wavelength range with a precision down to ≈1 nm and a full width at half maximum up to ≈273 nm. This effect allows maximal optoelectronic conversion using a basic silicon photodiode free of ambient interference. These findings enable a fast-response (≈20 ms) and low-threshold (≈kPa level) tactile stylus that can accurately authenticate signatures with the aid of machine learning algorithms in complex environments presenting moisture and light interference. © 2025 Wiley-VCH GmbH.

Original language	English
Article number	e16596
Number of pages	8
Journal	Advanced Materials
DOIs	https://doi.org/10.1002/adma.202516596
Publication status	Online published - 2 Nov 2025

Funding

H.S. and L.L. contributed equally to this work. This work was supported by the National Natural Science Foundation of China (No. 12474402), the Research Grants Council of Hong Kong (project no. CityU 11211922), the Central Government to Guide Local Scientific and Technological Development (236Z1013G), the Hebei Yanzhao Golden Platform Talent Gathering Programme Core Talent Project (Education Platform, HJYB202503), the Outstanding Youth Project of Natural Science Foundation of Hebei Province (A2025201031), the Natural Science Interdisciplinary Research Program of Hebei University (DXK202213).

Research Keywords

doping
mechanoluminescence
near-infrared
phosphor

RGC Funding Information

RGC-funded

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10.1002/adma.202516596

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title = "A Self-Powered Tactile Sensor Resistant to Environmental Interference",

abstract = "Developing advanced tactile sensors is important for cutting-edge applications such as human-machine interaction. However, the current tactile sensing technology primarily exploits triboelectrification, which is inherently susceptible to ambient interference, obstructing their real-world applications. Herein, a robust tactile sensing platform is presented that leverages piezoelectrics for mechano-optoelectronic transduction. A new class of ScBO3:Cr3+ crystals is developed that can produce intense broadband near-infrared light under sole mechanical pressure through self-recoverable mechanoluminescence (ML). Through a combinatorial doping strategy, deliberate modulation of ML profile is achieved across a broad wavelength range with a precision down to ≈1 nm and a full width at half maximum up to ≈273 nm. This effect allows maximal optoelectronic conversion using a basic silicon photodiode free of ambient interference. These findings enable a fast-response (≈20 ms) and low-threshold (≈kPa level) tactile stylus that can accurately authenticate signatures with the aid of machine learning algorithms in complex environments presenting moisture and light interference. {\textcopyright} 2025 Wiley-VCH GmbH.",

keywords = "doping, mechanoluminescence, near-infrared, phosphor",

author = "Hao Suo and Li Li and Jie Sun and Yu Zhang and Bo Zhao and Xian Zheng and Yu Wang and Guodong Zhang and Zhijun Wang and Panlai Li and Daqing Yang and Xin Zhang and Feng Wang",

year = "2025",

month = nov,

day = "2",

doi = "10.1002/adma.202516596",

language = "English",

journal = "Advanced Materials",

issn = "0935-9648",

publisher = "Wiley-Blackwell",

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TY - JOUR

T1 - A Self-Powered Tactile Sensor Resistant to Environmental Interference

AU - Suo, Hao

AU - Li, Li

AU - Sun, Jie

AU - Zhang, Yu

AU - Zhao, Bo

AU - Zheng, Xian

AU - Wang, Yu

AU - Zhang, Guodong

AU - Wang, Zhijun

AU - Li, Panlai

AU - Yang, Daqing

AU - Zhang, Xin

AU - Wang, Feng

PY - 2025/11/2

Y1 - 2025/11/2

N2 - Developing advanced tactile sensors is important for cutting-edge applications such as human-machine interaction. However, the current tactile sensing technology primarily exploits triboelectrification, which is inherently susceptible to ambient interference, obstructing their real-world applications. Herein, a robust tactile sensing platform is presented that leverages piezoelectrics for mechano-optoelectronic transduction. A new class of ScBO3:Cr3+ crystals is developed that can produce intense broadband near-infrared light under sole mechanical pressure through self-recoverable mechanoluminescence (ML). Through a combinatorial doping strategy, deliberate modulation of ML profile is achieved across a broad wavelength range with a precision down to ≈1 nm and a full width at half maximum up to ≈273 nm. This effect allows maximal optoelectronic conversion using a basic silicon photodiode free of ambient interference. These findings enable a fast-response (≈20 ms) and low-threshold (≈kPa level) tactile stylus that can accurately authenticate signatures with the aid of machine learning algorithms in complex environments presenting moisture and light interference. © 2025 Wiley-VCH GmbH.

AB - Developing advanced tactile sensors is important for cutting-edge applications such as human-machine interaction. However, the current tactile sensing technology primarily exploits triboelectrification, which is inherently susceptible to ambient interference, obstructing their real-world applications. Herein, a robust tactile sensing platform is presented that leverages piezoelectrics for mechano-optoelectronic transduction. A new class of ScBO3:Cr3+ crystals is developed that can produce intense broadband near-infrared light under sole mechanical pressure through self-recoverable mechanoluminescence (ML). Through a combinatorial doping strategy, deliberate modulation of ML profile is achieved across a broad wavelength range with a precision down to ≈1 nm and a full width at half maximum up to ≈273 nm. This effect allows maximal optoelectronic conversion using a basic silicon photodiode free of ambient interference. These findings enable a fast-response (≈20 ms) and low-threshold (≈kPa level) tactile stylus that can accurately authenticate signatures with the aid of machine learning algorithms in complex environments presenting moisture and light interference. © 2025 Wiley-VCH GmbH.

KW - doping

KW - mechanoluminescence

KW - near-infrared

KW - phosphor

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U2 - 10.1002/adma.202516596

DO - 10.1002/adma.202516596

M3 - RGC 21 - Publication in refereed journal

SN - 0935-9648

JO - Advanced Materials

JF - Advanced Materials

M1 - e16596

ER -

A Self-Powered Tactile Sensor Resistant to Environmental Interference

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Research Keywords

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GRF: Multichromatic Construction in Self-powered Interactive Sensing Display via Triboelectrification-induced Electroluminescence

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A Self-Powered Tactile Sensor Resistant to Environmental Interference

Abstract

Funding

Research Keywords

RGC Funding Information

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GRF: Multichromatic Construction in Self-powered Interactive Sensing Display via Triboelectrification-induced Electroluminescence

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