光电探测器
计算机科学
材料科学
人工神经网络
推论
钙钛矿(结构)
图形
激光阈值
带隙
拓扑(电路)
邻接表
算法
空间映射
人工智能
高保真
光电子学
参数空间
深度学习
电子工程
联轴节(管道)
忠诚
分路器
卷积神经网络
阻带
作者
Shiyang Lei,Baoyi An,Guoqiang Peng,Xiangzheng Chen,Hao Jia,Zhiwen Jin
标识
DOI:10.1002/adom.202502871
摘要
ABSTRACT Inorganic ABX 3 perovskites have exceptional optoelectronic properties, yet efficiently navigating their vast chemical space for high‐performance photodetectors remains challenged by the trade‐off between computational fidelity and screening efficiency. To overcome this bottleneck, we develop a hierarchical physics‐aware graph neural network (PAGNN) framework featuring a novel Dynamic RBF Modulation mechanism. Our model achieves deep coupling of chemical priors with geometric equivariance. Crucially, we implement a three‐stage curriculum learning strategy to bridge the fidelity gap between standard PBE and high‐precision mBJ functionals. For photodetector and optoelectronic applications, we predict band gaps and formation energies as well as hull energies, achieving mean absolute errors of 0.11 eV and 0.06 eV/atom, respectively. Validation Structure‐Unseen Split protocol demonstrates the model's superior structural inference capability. Applying our model to screen promising ABX 3 candidates and guide the continuous compositional engineering of solid solutions, we recover known high‐performance perovskites and identify novel compounds for optoelectronic integration. Ultimately, this work establishes a generalizable, data‐efficient, and interpretable paradigm for accelerated materials discovery.
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