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Biography
(只提供英文版)

  • Professor in Department of Applied Physics at The Hong Kong Polytechnic University
  • Research interests include 2D materials, electron microscopy, nanomaterials
  • RFS project — In 2D bilayer h-BN or 2D TMDs, the Moiré pattern in marginally twisted bilayers aligns with the out-of-plane ferroelectric domain pattern. The domain structures (e.g., AB or BA stacking area) can be controlled by an external electric field. This project aims to explore the dissipation, fatigue and domain switching mechanisms of these innovative vdW 2D ferroelectrics, with a specific focus on domain wall kinetics. It will consider the influence of twist angles and stacking orders. Larger twist angles or cases of incommensurate stacking may introduce low friction interlayer sliding or even superlubricity in between the layers, potentially exhibiting even lower dissipation compared to marginally twisted bilayers for domain wall motion. Moreover, the unique in-plane vortex domain structures in twisted bilayers might introduce novel domain wall dynamics and inspire the development of future device structures. The objective of this project is to minimize energy dissipation for the domain kinetics and minimize fatigue for the ferroelectric switching, with the ultimate goal of achieving ultrafast speed, minimal energy loss, fatigue-free and optimal recyclability in 2D twisting-layered ferroelectric devices.
  • Awards and Honours:
    • RGC Research Fellow (2025)
    • NSFC Distinguished Young Scholar (2025)
    • Hong Kong Academy of Engineering, Young Member Section (YMS) (2025)

Project Title
(只提供英文版)

  • From Slidetronics to Twistronics: A Twisting Platform for Dissipationless Ferroelectricity

讚詞

趙炯教授獲得香港研資局「研究學者計劃」資助,旨在探索創新型范德華二維鐵電體的耗散、疲勞和疇切換機制,並特別關注疇壁動力學。

 

在二維雙層h-BN或二維TMD中,邊緣扭轉雙層中的莫爾條紋與平面外鐵電疇圖案一致。疇結構(例如AB或BA堆疊區域)可以透過外部電場控制。相鄰范德華(vdW)層之間的鐵電疇壁運動能夠實現超快且穩定的「滑動電子學」和「扭轉電子學」,同時最大程度地減少電荷釘扎和機械摩擦,為未來的鐵電器件帶來光明的前景。

 

這項計畫將考慮扭轉角和堆疊順序的影響。較大的扭曲角或不相稱堆疊的情況可能會在層間引入低摩擦層間滑動甚至超潤滑,與小扭曲的雙層相比,疇壁運動可能表現出更低的耗散。此外,扭曲雙層中獨特的平面內渦旋疇結構可能會引入新的疇壁動力學並啟發未來器件結構的發展。 二维扭曲層狀鐵電器件中實現超快的速度、最小的能量損失、無疲勞和最佳的可重复性。