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Main Authors: Zhou, Shaokai, Cai, Haihui, Wu, Yehao, Min, Yufeng, Yuan, Renchen, Lv, Yezhu, Huang, Jianming, Shi, Yuanyuan, Illarionov, Yury Yuryevich
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.16526
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author Zhou, Shaokai
Cai, Haihui
Wu, Yehao
Min, Yufeng
Yuan, Renchen
Lv, Yezhu
Huang, Jianming
Shi, Yuanyuan
Illarionov, Yury Yuryevich
author_facet Zhou, Shaokai
Cai, Haihui
Wu, Yehao
Min, Yufeng
Yuan, Renchen
Lv, Yezhu
Huang, Jianming
Shi, Yuanyuan
Illarionov, Yury Yuryevich
contents MoS$_2$ field-effect transistors (FETs) with high-\textit{k} oxides currently lag behind silicon standards in bias and temperature stability due to ubiquitous border oxide traps that cause clockwise (CW) hysteresis in gate transfer characteristics. While suppressing this effect is typically mandatory for logic FETs, here we explore an alternative strategy where the initial CW hysteresis can be dynamically overcome by stronger counterclockwise (CCW) hysteresis towards memory-like dynamics. We systematically compare hysteresis in similar back-gated MoS$_2$/HfO$_2$ and MoS$_2$/Al$_2$O$_3$ FETs up to 275\textdegree C. At room temperature, both devices initially show sizable CW hysteresis. However, at 175\textdegree C MoS$_2$/HfO$_2$ FETs exhibit dominant CCW dynamics coupled with self-doping and negative differential resistance (NDR) effects. Our compact model suggests that this behavior is caused by the drift of mobile oxygen vacancies (\textit{V}\({}_{\mathrm{O}}^{+}\) or \textit{V}\({}_{\mathrm{O}}^{2+}\)) within HfO$_2$ which also causes negative $V_{\mathrm{th}}$ shift under a constant positive bias stress. This alternative mechanism effectively overrides the initial CW hysteresis and enables intrinsic memory functionality that can be enhanced by using narrower gate bias sweep ranges. In contrast, the MoS$_2$/Al$_2$O$_3$ FETs display only minor CCW dynamics even at 275\textdegree C due to higher drift activation energies for the same vacancies, thereby maintaining superior stability. Our results reveal an insulators selection paradigm: Al$_2$O$_3$ layers are better suited to suppress detrimental negative $V_{\mathrm{th}}$ shifts in MoS$_2$ logic FETs at high temperatures, whereas their HfO$_2$ counterparts can serve as active memory layers that would exploit these abnormal instabilities.
format Preprint
id arxiv_https___arxiv_org_abs_2601_16526
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Mobile charges in MoS2/high-k oxide transistors: from abnormal instabilities to memory-like dynamics
Zhou, Shaokai
Cai, Haihui
Wu, Yehao
Min, Yufeng
Yuan, Renchen
Lv, Yezhu
Huang, Jianming
Shi, Yuanyuan
Illarionov, Yury Yuryevich
Materials Science
MoS$_2$ field-effect transistors (FETs) with high-\textit{k} oxides currently lag behind silicon standards in bias and temperature stability due to ubiquitous border oxide traps that cause clockwise (CW) hysteresis in gate transfer characteristics. While suppressing this effect is typically mandatory for logic FETs, here we explore an alternative strategy where the initial CW hysteresis can be dynamically overcome by stronger counterclockwise (CCW) hysteresis towards memory-like dynamics. We systematically compare hysteresis in similar back-gated MoS$_2$/HfO$_2$ and MoS$_2$/Al$_2$O$_3$ FETs up to 275\textdegree C. At room temperature, both devices initially show sizable CW hysteresis. However, at 175\textdegree C MoS$_2$/HfO$_2$ FETs exhibit dominant CCW dynamics coupled with self-doping and negative differential resistance (NDR) effects. Our compact model suggests that this behavior is caused by the drift of mobile oxygen vacancies (\textit{V}\({}_{\mathrm{O}}^{+}\) or \textit{V}\({}_{\mathrm{O}}^{2+}\)) within HfO$_2$ which also causes negative $V_{\mathrm{th}}$ shift under a constant positive bias stress. This alternative mechanism effectively overrides the initial CW hysteresis and enables intrinsic memory functionality that can be enhanced by using narrower gate bias sweep ranges. In contrast, the MoS$_2$/Al$_2$O$_3$ FETs display only minor CCW dynamics even at 275\textdegree C due to higher drift activation energies for the same vacancies, thereby maintaining superior stability. Our results reveal an insulators selection paradigm: Al$_2$O$_3$ layers are better suited to suppress detrimental negative $V_{\mathrm{th}}$ shifts in MoS$_2$ logic FETs at high temperatures, whereas their HfO$_2$ counterparts can serve as active memory layers that would exploit these abnormal instabilities.
title Mobile charges in MoS2/high-k oxide transistors: from abnormal instabilities to memory-like dynamics
topic Materials Science
url https://arxiv.org/abs/2601.16526