Dual-mode 0D/2D Spatial Asymmetry Optoelectronic Device Enabled by in situ Microzone Femtosecond Laser Deposition

To develop artificial intelligence and humanoid robotics, it is crucial to fabricate advanced vision systems with high efficiency and versatility. A key challenge is the functional integration of high-speed photodetectors (PDs) and neuromorphic vision sensors (NVSs) into a single device, as current studies suffer from complex architectures or fabrication processes. Hence, we propose a Microzone Femtosecond Laser Deposition (M-FLD) technique that enables the localized, in situ deposition of zero-dimensional (0D) black phosphorus (BP) nanoparticles onto a two-dimensional (2D) MoS ₂ channel by ablating a micro-scale solid-state target. By M-FLD and h-BN nanomask, we fabricated a spatial asymmetric 0D/2D heterostructure for highly integrated dual-mode optoelectronic device. By changing the direction of V _ds , the device can be converted from PD to NVS. Under the PD mode, the device can sense high-frequency optical signals up to 250 Hz. Under the NVS mode, the device’s optical energy consumption per activity is only 191.2 pJ. Based on the sensing and memory capabilities, the device is simulated for MNIST handwritten digit recognition, achieving an accuracy of up to 96.20%. This work provides a flexible and powerful platform for fabricating complex heterostructures, paving the way for highly integrated and reconfigurable neuromorphic vision systems.