铁电性
材料科学
纳米尺度
凝聚态物理
原子探针
极化(电化学)
联轴节(管道)
化学物理
聚类分析
异质结
钪
光电子学
纳米技术
反向
快速傅里叶变换
纤锌矿晶体结构
压电
Atom(片上系统)
作者
Shaon Das,Thai-Son Nguyen,Chandrashekar Savant,Karthick Gothandapani,Huili Grace Xing,Debdeep Jena,Baishakhi Mazumder
摘要
Al1−xScxN (AlScN) has emerged as a promising ferroelectric material for next-generation memory and logic devices; yet its performance remains limited by poor understanding of nanoscale structural instabilities. Here, we uncover intrinsic short-range chemical ordering and strain–defect coupling in molecular-beam-epitaxy grown Al0.66Sc0.34N using a combination of atom probe tomography and transmission electron microscopy. The heterostructure exhibits wurtzite structure with a sharp and clean AlScN/AlN interface with negligible interdiffusion. Frequency distribution and radial distribution analyses reveal statistically significant Sc–Sc enrichment and Sc–N depletion, indicating nanoscale clustering accompanied by local nitrogen deficiency. Corresponding lattice-spacing variations observed by inverse FFT mapping confirm strain variation correlated with Sc-rich domains. These results provide the first atom-by-atom experimental evidence of scandium clustering and its coupling to nitrogen-vacancy formation in the ferroelectric composition regime. These findings identify short-range ordering and strain–defect coupling as intrinsic structural features of ferroelectric AlScN, with important implications for polarization switching behavior and reliability.
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