Your search keyword '"Han, Zheng Vitto"' showing total 2 results

1. Electrically and Magnetically Tunable Valley Polarization in Monolayer MoSe2 Proximitized by a 2D Ferromagnetic Semiconductor.

Author

Zhang, Tongyao, Zhao, Siwen, Wang, Anran, Xiong, Zhiren, Liu, Yingjia, Xi, Ming, Li, Songlin, Lei, Hechang, Han, Zheng Vitto, and Wang, Fengqiu

Subjects

SEMICONDUCTORS, FERROMAGNETIC materials, MAGNETIC traps, MONOMOLECULAR films, TRANSITION metals, INTERNAL friction

Abstract

The emergence of atomically thin valleytronic semiconductors and 2D ferromagnetic materials is opening up new technological avenues for future information storage and processing. A key fundamental challenge is to identify physical knobs that may effectively manipulate the spin‐valley polarization, preferably in the device context. Here, a novel spin functional device that exhibits both electrical and magnetic tunability is fabricated, by contacting a monolayer MoSe2 with a 2D ferromagnetic semiconductor Cr2Ge2Te6. Remarkably, the valley‐polarization of MoSe2 is found to be controlled by a back‐gate voltage with an appreciably enlarged valley splitting rate. At fixed gate voltages, the valley‐polarization exhibits magnetic‐field and temperature dependence that corroborates well with the intrinsic magnetic properties of Cr2Ge2Te6, pointing to the impact of magnetic exchange interactions. Due to the interfacial arrangement, the charge‐carrying trion photoemission predominates in the devices, which may be exploited to enable drift‐based spin‐optoelectronic devices. These results provide new insights into valley‐polarization manipulation in transition metal dichalcogenides by means of ferromagnetic semiconductor proximitizing and represent an important step forward in devising field‐controlled 2D magneto‐optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2022

2. Correlated states in doubly-aligned hBN/graphene/hBN heterostructures.

Author

Sun, Xingdan, Zhang, Shihao, Liu, Zhiyong, Zhu, Honglei, Huang, Jinqiang, Yuan, Kai, Wang, Zhenhua, Watanabe, Kenji, Taniguchi, Takashi, Li, Xiaoxi, Zhu, Mengjian, Mao, Jinhai, Yang, Teng, Kang, Jun, Liu, Jianpeng, Ye, Yu, Han, Zheng Vitto, and Zhang, Zhidong

Subjects

HETEROSTRUCTURES, CRYSTAL symmetry, GRAPHENE, BORON nitride, NANOSTRUCTURED materials, SUPERLATTICES

Abstract

Interfacial moiré superlattices in van der Waals vertical assemblies effectively reconstruct the crystal symmetry, leading to opportunities for investigating exotic quantum states. Notably, a two-dimensional nanosheet has top and bottom open surfaces, allowing the specific case of doubly aligned super-moiré lattice to serve as a toy model for studying the tunable lattice symmetry and the complexity of related electronic structures. Here, we show that by doubly aligning a graphene monolayer to both top and bottom encapsulating hexagonal boron nitride (h-BN), multiple conductivity minima are observed away from the main Dirac point, which are sensitively tunable with respect to the small twist angles. Moreover, our experimental evidences together with theoretical calculations suggest correlated insulating states at integer fillings of −5, −6, −7 electrons per moiré unit cell, possibly due to inter-valley coherence. Our results provide a way to construct intriguing correlations in 2D electronic systems in the weak interaction regime. The alignment of three 2D nanosheets leads to the formation of super-moiré atomic lattices, which can influence the electronic properties of van der Waals structures. Here, the authors report evidence of possible correlated insulating states in doubly-aligned hBN/graphene/hBN heterostructures, in a weak-interaction regime. [ABSTRACT FROM AUTHOR]

Published

2021