ABSTRACT Integrating event detection and grayscale sensing in a single pixel/transistor enables compact, intelligent, flexible neuromorphic spatiotemporal visual imaging. Memory phototransistors based on organic phase‐change semiconductors (OPCSs) are promising due to the high theoretical photo‐sensing‐storage capacity, excellent conductance linearity/symmetry, and intrinsic flexibility. However, such systems are constrained by low phase‐change efficiency (narrow memory window/capacity) arising from weak and poorly controllable organic molecular interactions, restricting complex feature extraction and increasing energy consumption during information perception and processing. Here, we propose a single‐crystal PZT‐driven piezo‐phototronic organic adaptive memory transistor (OAMT) with optimized stress distribution and multi‐field control, significantly enhancing molecular conformation transition efficiency under low‐power operation. The device achieves a record memory window capacity factor ( γ ) of ∼0.87 at a subthreshold swing ( SS ) of 200 mV/decade, with over 90% recognition accuracy from the OAMT device's actual LTP/LTD synaptic functions in neuromorphic simulations. Furthermore, the device's adaptive multistage phase‐transition behavior in response to varying UV pulse densities enables stable current changes—transitioning from molecular conformation 2 to mixed conformations (1+2) in the PCS layer—as well as transient current spikes from conformation 2 to 1. The device simulates real‐time flight attitude and dynamic grayscale detection via precise spatio‐temporal synchronization, showing great potential for advanced visual technology.
Xu et al. (Tue,) studied this question.
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