化学
钙钛矿(结构)
正交晶系
结晶学
电子结构
凝聚态物理
原子轨道
八面体
同步加速器
晶体结构
金属
化学物理
衍射
费米能级
卤化物
过渡金属
相变
吸收光谱法
轨道杂交
铁磁性
体积模量
电子衍射
相(物质)
分子物理学
X射线晶体学
格子(音乐)
晶格常数
失真(音乐)
环境压力
电子
作者
Mei Li,Pengfei Shan,Bohao Zhao,Yiming Wang,Kejun Bu,Junlong Li,Hao Wang,Tingting Zhao,Shang Peng,Dongliang Yang,Sheng Jiang,Jiao An,Jinguang Cheng,Wenge Yang,Xujie Lü,Chuanlong Lin
摘要
Distinct from traditional halide perovskites, which are based on main-group elements (e.g., Pb2+, Sn2+, Ge2+) and are typically semiconducting, transition metals like Cu2+─characterized by partially filled d-orbitals─offer unique advantages in modulating the electronic behavior of perovskite materials. However, the strong Jahn–Teller effect of Cu2+ makes it a significant challenge for stabilizing a robust three-dimensional perovskite framework. Herein, we report the first synthesis of a metallic cubic perovskite phase of CsCuBr3 via a tailored structural design under high-temperature and high-pressure conditions. In situ synchrotron X-ray diffraction reveals that the orthorhombic nonperovskite CsCuBr3 precursor (space group C2221) transforms into a cubic perovskite structure (space group Pm-3m) featuring an undistorted corner-sharing octahedral framework at ∼22 GPa and ∼603 K. The perovskite structure remains stable at pressure down to 4.3 GPa at room temperature, while at low temperatures below 50 K, it may be recovered to ambient pressure. Notably, the structure lacks both the expected luminescence and a distinct absorption edge, instead exhibiting a metallic behavior, as confirmed by temperature-dependent resistance measurements. Electronic structure calculations at 22.4 GPa and 0 K further reveal pronounced hybridization between the Cu-3d and Br-4p orbitals near the Fermi level, leading to an enhanced orbital degeneracy and electron delocalization. These findings demonstrate that the lattice contraction effectively suppresses the strong Jahn–Teller distortion intrinsic to Cu2+, offering a promising strategy for the design of high-performance novel materials.
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