Broadband-Detection and Low-Operating-Voltage Photodetectors Based on Metal Oxide/Perovskite Quantum Dot Heterojunctions

To achieve comprehensive environmental monitoring, photodetectors with broad operational wavelength range are crucial for capturing realistic wide-spectrum signals and supporting integrated system operations. This study presents a high-performance photodetector based on InSrO nanofiber (NF)/CsPbBr₃ quantum dot (QD) heterojunctions, achieving broadband detection (230-500 nm) and ultralow operating voltage (0.05 V). By synergistically combining the UV absorption of InSrO NFs with the visible-light sensitivity of CsPbBr₃ QDs, the device exhibits a responsivity of 6.88 A·W^-1 and a detectivity of 6.39 × 10¹⁴ Jones. Systematic analysis reveals that the heterointerface facilitates efficient charge separation, while the 1D nanofiber architecture enhances directional carrier transport. Notably, the photodetectors can retain 95% of the initial photocurrent after 15 days, demonstrating exceptional stability. This work can advance the development of energy-efficient optoelectronic devices for environmental monitoring and optical communications applications.