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Article Abstract
Tactile sensors utilizing functional materials decode surface textures for object recognition. Herein, we engineer a donor-acceptor fluorescent material, MNIMP, that synergizes aggregation-induced emission (AIE) and twisted intramolecular charge transfer (TICT) mechanisms. Contact-induced nanoflake assembly on the MNIMP film triggers fluorescence amplification mediated by the combined AIE and TICT effects, through which the surface morphology of textured objects can be accurately visualized as fluorescent patterns. MNIMP maps micro-textures of materials such as rubber, fabrics, and elastic polymers under tactile pressure with kPa-level sensitivity, seamlessly integrating visual and tactile perceptions. These fluorescent signatures can be recognized using a deep-learning model with >98% accuracy. Hardware integration with the embedded algorithm model creates an intelligent tactile sensor system performing concurrent contact imaging, data analysis, and classification. This intelligent platform demonstrates micron-scale resolution and cost-effective manufacturability while maintaining high signal fidelity across diverse target objects.
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