杰纳斯
极化(电化学)
铁电性
凝聚态物理
材料科学
范德瓦尔斯力
双层
单层
电荷密度
缩放比例
格子(音乐)
极化密度
电场
密度泛函理论
激发极化
光电子学
超晶格
电压
异质结
杰纳斯粒子
电介质
作者
Diyu Dong,Yupan Peng,Chengshun Liu,Yuqi Xia,Sicheng Liu,Peng Zhang,Zhe Wang
出处
期刊:Physical review
[American Physical Society]
日期:2025-11-05
卷期号:112 (20)
被引量:3
摘要
Sliding ferroelectricity, characterized by an out-of-plane electric polarization originating from asymmetric interlayer charge distribution in noncentrosymmetric van der Waals bilayers or multilayers, suffers from generally low polarization. Here, we propose that interface charge density enhancement is a key mechanism for increasing out-of-plane polarization in sliding ferroelectrics, which is demonstrated through first-principles calculations on two-dimensional Janus material MoSeS. The tail-to-tail stacked MoSeS bilayer (t-MoSeS) exhibits significantly larger polarization than other bilayers, which mainly origins from reduced interlayer distances and enhanced interlayer charge accumulation due to Janus structures. A systematic analysis reveals that the polarization of t-MoSeS displays heightened (reduced) sensitivity to interlayer distance (lattice constant), resulting in the Janus-induced polarization enhancement $(\mathrm{\ensuremath{\Delta}}P)$ amplified at smaller interlayer distances and lattice constants. Furthermore, we theoretically verify the scaling law $\mathrm{\ensuremath{\Delta}}P\ensuremath{\propto}{P}_{0}^{2}$, directly linking the polarization enhancement to the Janus monolayer polarity $({P}_{0})$. Our work establishes interface charge engineering as a fundamental design principle for high-polarization sliding ferroelectrics, with Janus materials providing a promising implementation pathway, resolving the structure-charge-polarization interplay and advancing the frontier of two-dimensional ferroelectric materials.
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