The monolithic integration of 2D materials into silicon-based wafers is crucial for next-generation electronics and optoelectronics. Reliable transfer methods for wafer-scale 2D materials are a key prerequisite. As one of the most promising 2D semiconductors, bismuth oxygen selenide (Bi2O2Se) films show significant promise as high-performance photodetectors and advanced-architecture transistors. Although considerable efforts have been devoted to transfer methods for 2D Bi2O2Se, challenges such as limited film size, transfer-induced defects, cracks, and contamination remain. Herein, we report a novel transfer method for wafer-scale 2D Bi2O2Se single-crystal films based on the stress modulation of metal films. A composite transfer medium comprising tensile-stressed Ni and stress-free Cu was developed to enable intact and crack-free exfoliation of 2D Bi2O2Se films. By modulating the strain and fracture energies of the composite metal film, the transferred 4-inch 2D Bi2O2Se film exhibited a crack-free, intact, and uniform morphology, and two-layer and three-layer-stacked 2D Bi2O2Se films with clean interfaces were fabricated. Integrated 2D Bi2O2Se transistors exhibit high carrier mobility reaching up to ∼150 cm2 V-1 s-1 with an on/off ratio ∼106, which is better than other transferred wafer-scale 2D semiconductors. Overall, our findings are promising for the future integration of 2D materials into advanced electronics and optoelectronics.
Gao et al. (Thu,) studied this question.
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