Liubin Yang, Xiushuo Gu, Min Zhou, Jianya Zhang, Yonglin Huang, Yukun Zhao. Deep-UV-photo-excited synaptic Ga2O3 nano-device with low-energy consumption for neuromorphic computing[J]. Journal of Semiconductors, 2024, 45(0): -1. doi: 10.1088/1674-4926/24050037.
L B Yang, X S Gu, M Zhou, J Y Zhang, Y L Huang, and Y K Zhao, Deep-UV-photo-excited synaptic Ga2O3 nano-device with low-energy consumption for neuromorphic computing[J]. J. Semicond., 2024, accepted. doi: 10.1088/1674-4926/24050037.Export: BibTex EndNote
Synaptic nano-devices have powerful capabilities in logic, memory and learning, making them essential components for constructing brain-like neuromorphic computing systems. Here, we have successfully developed and demonstrated a synaptic nano-device based on Ga2O3 nanowires with low energy consumption. Under 255 nm light stimulation, the biomimetic synaptic nano-device can stimulate various functionalities of biological synapses, including pulse facilitation, peak time-dependent plasticity and memory learning ability. It is found that the artificial synaptic device based on Ga2O3 nanowires can achieve an excellent "learning-forgetting-relearning" functionality. The transition from short-term memory to long-term memory and retention of the memory level after the stepwise learning can attribute to the great relearning functionality of Ga2O3 nanowires. Furthermore, the energy consumption of the synaptic nano-device can be lower than 2.39 × 10‒11 J for a synaptic event. Moreover, our device demonstrates exceptional stability in long-term stimulation and storage. In the application of neural morphological computation, the accuracy of digit recognition exceeds 90% after 12 training sessions, indicating the strong learning capability of the cognitive system composed of this synaptic nano-device. Therefore, our work paves an effective way for advancing hardware-based neural morphological computation and artificial intelligence systems requiring low power consumption.
Synaptic nano-devices have powerful capabilities in logic, memory and learning, making them essential components for constructing brain-like neuromorphic computing systems. Here, we have successfully developed and demonstrated a synaptic nano-device based on Ga2O3 nanowires with low energy consumption. Under 255 nm light stimulation, the biomimetic synaptic nano-device can stimulate various functionalities of biological synapses, including pulse facilitation, peak time-dependent plasticity and memory learning ability. It is found that the artificial synaptic device based on Ga2O3 nanowires can achieve an excellent "learning-forgetting-relearning" functionality. The transition from short-term memory to long-term memory and retention of the memory level after the stepwise learning can attribute to the great relearning functionality of Ga2O3 nanowires. Furthermore, the energy consumption of the synaptic nano-device can be lower than 2.39 × 10‒11 J for a synaptic event. Moreover, our device demonstrates exceptional stability in long-term stimulation and storage. In the application of neural morphological computation, the accuracy of digit recognition exceeds 90% after 12 training sessions, indicating the strong learning capability of the cognitive system composed of this synaptic nano-device. Therefore, our work paves an effective way for advancing hardware-based neural morphological computation and artificial intelligence systems requiring low power consumption.
L B Yang, X S Gu, M Zhou, J Y Zhang, Y L Huang, and Y K Zhao, Deep-UV-photo-excited synaptic Ga2O3 nano-device with low-energy consumption for neuromorphic computing[J]. J. Semicond., 2024, accepted. doi: 10.1088/1674-4926/24050037.