Multifunctional Tactile Sensor with Multimodal Capabilities for Pressure, Temperature, and Surface Recognition

Viet Anh Cao, Van Quan Phan,Nam Khanh Nguyen,Minje Kim,Phuoc Cao Van,Hieu Nguyen Minh,Soo Young Kim,Junghyo Nah

Nano Energy（2025）

Department of Electrical Engineering

Cited 0|Views4

Abstract

Tactile perception, a vital sensory function, enables humans to interact directly with their environment, responding to various stimuli such as pressure, temperature, and texture. Recent advancements in functional materials and micro-nano fabrication have led to the development of highly flexible tactile sensors with excellent spatial resolution and sensitivity. However, replicating the complexity of human tactile perception remains challenging, necessitating innovative sensor designs that can mimic human touch. This study presents a multifunctional tactile sensor with multimodal capabilities, capable of simultaneously detecting pressure, temperature, and surface properties by integrating distinct sensing mechanisms. The sensor utilizes PVDF/Ti3C2 and PVDF-TrFE/Ti3C2 composites for static and dynamic pressure sensing, respectively, and PEDOT: PSS/Ti3C2 for temperature measurement. Additionally, a triboelectric layer with patterned PDMS enables effective surface differentiation. Each sensing layer was integrated using a hot rolling press technique, with Ti3C2 enhancing the sensor's conductivity, piezoelectric performance, and thermal sensitivity. The multimodal sensor demonstrates simultaneous detection of static and dynamic stimuli, temperature variations, and surface material properties, making it suitable for advanced applications in robotics and healthcare where complex tactile feedback is essential.

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Key words

Ti3C2 – Mxene,Pressure sensor,Temperature sensor,Surface recognition,Multifunctional tactile sensor,Multimodal capabilities

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Pretraining has recently greatly promoted the development of natural language processing (NLP)
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