Litcius/Paper detail

Sub-nanosecond polarization switching with anomalous kinetics in vdW ferroelectric WTe2

Yinxin Bai, Zhichao Yu, Zeyu Guan, Junjiang Tian, Chuanshou Wang, Xiaodong Yao, Yihao Yang, Yunlin Lei, Jing‐Bo Xu, Chenhao Liu, Jinlong Zhu, Yuchen Tu, Shengchun Shen, Hongjun Xiang, Xiaoguang Li, Changsong Xu, Junling Wang

2025Nature Communications15 citationsDOIOpen Access PDF

Abstract

Recently discovered “sliding ferroelectrics” exhibit distinct polarization origin and switching mechanism compared to conventional ferroelectric materials. However, a clear understanding of the polarization switching kinetics remains lacking. Here, we demonstrate sub-nanosecond (0.6 ns) polarization switching in the sliding ferroelectrics WTe2, which is the fastest switching observed so far in van der Waals ferroelectrics. Furthermore, the conventional nucleation-limited-switching model can still be applied to describe the switching process. However, contrary to conventional ferroelectric materials, the activation field associated with polarization reversal increases with temperature. Theoretical analysis suggests that this behavior is linked to the charge transfer nature of polarization in WTe2 and the unique sliding mechanism for polarization switching. Additionally, the device demonstrates remarkable endurance, with no fatigue observed after 1010 switching cycles. This study provides valuable insights into the polarization reversal process in sliding ferroelectrics and paves the way for future advances in nanoelectronic and spintronic applications. The authors systematically investigate the polarization switching kinetics of sliding ferroelectric WTe2, demonstrating their ultrafast response (0.6 ns).

Topics & Concepts

NanosecondFerroelectricityKineticsPolarization (electrochemistry)Materials scienceOptoelectronicsCondensed matter physicsPhysicsChemistryOpticsDielectricLaserPhysical chemistryQuantum mechanics2D Materials and ApplicationsAdvanced Memory and Neural ComputingElectronic and Structural Properties of Oxides