Abstract: Neuromorphic computing continues to advance, fueling the pursuit of enhanced information processing and learning capabilities. This study introduces a novel photonic synaptic transistor (PST) based on crystallized conjugated polymers. Engineered to efficiently respond to standard temporal signals and digital images, this PST mimics the human retina's in-sensor computing mechanism. Developed through low-temperature solvent engineering, the PST optimizes charge carrier mobility and light absorption by finely tuning the polymer's microstructure. In a groundbreaking application, this PST has been used for image classification and Morse code recognition within reservoir computing frameworks. The polymer's microstructure modulation notably enhances the device's short-term and long-term plasticity, synaptic weight update efficiency, and training and recognition accuracy. These advancements underscore the potential of crystallized conjugated polymer-based PSTs to revolutionize next-generation neuromorphic computing systems.

Key words: Photonic synaptic transistor, Crystallized conjugated polymers, Short-term plasticity, Long-term plasticity, Reservoir computing