Your search keyword '"Weber, Bent"' showing total 4 results

1. Symmetry Breaking and Spin–Orbit Coupling for Individual Vacancy-Induced In-Gap States in MoS2Monolayers

Author

Aliyar, Thasneem, Ma, Hongyang, Krishnan, Radha, Singh, Gagandeep, Chong, Bi Qi, Wang, Yitao, Verzhbitskiy, Ivan, Yu Wong, Calvin Pei, Johnson Goh, Kuan Eng, Shen, Ze Xiang, Koh, Teck Seng, Rahman, Rajib, and Weber, Bent

Abstract

Spins confined to point defects in atomically thin semiconductors constitute well-defined atomic-scale quantum systems that are being explored as single-photon emitters and spin qubits. Here, we investigate the in-gap electronic structure of individual sulfur vacancies in molybdenum disulfide (MoS2) monolayers using resonant tunneling scanning probe spectroscopy in the Coulomb blockade regime. Spectroscopic mapping of defect wave functions reveals an interplay of local symmetry breaking by a charge-state-dependent Jahn–Teller lattice distortion that, when combined with strong (≃100 meV) spin–orbit coupling, leads to a locking of an unpaired spin-1/2 magnetic moment to the lattice at low temperature, susceptible to lattice strain. Our results provide new insights into the spin and electronic structure of vacancy-induced in-gap states toward their application as electrically and optically addressable quantum systems.

Published

2024

2. Direct Observation of 2D Electrostatics and Ohmic Contacts in Template-Grown Graphene/WS2Heterostructures

Author

Zheng, Changxi, Zhang, Qianhui, Weber, Bent, Ilatikhameneh, Hesameddin, Chen, Fan, Sahasrabudhe, Harshad, Rahman, Rajib, Li, Shiqiang, Chen, Zhen, Hellerstedt, Jack, Zhang, Yupeng, Duan, Wen Hui, Bao, Qiaoliang, and Fuhrer, Michael S.

Abstract

Large-area two-dimensional (2D) heterojunctions are promising building blocks of 2D circuits. Understanding their intriguing electrostatics is pivotal but largely hindered by the lack of direct observations. Here graphene–WS2heterojunctions are prepared over large areas using a seedless ambient-pressure chemical vapor deposition technique. Kelvin probe force microscopy, photoluminescence spectroscopy, and scanning tunneling microscopy characterize the doping in graphene–WS2heterojunctions as-grown on sapphire and transferred to SiO2with and without thermal annealing. Both p–n and n–n junctions are observed, and a flat-band condition (zero Schottky barrier height) is found for lightly n-doped WS2, promising low-resistance ohmic contacts. This indicates a more favorable band alignment for graphene–WS2than has been predicted, likely explaining the low barriers observed in transport experiments on similar heterojunctions. Electrostatic modeling demonstrates that the large depletion width of the graphene–WS2junction reflects the electrostatics of the one-dimensional junction between two-dimensional materials.

Published

2017

3. Spin-Valley Locking for In-Gap Quantum Dots in a MoS2Transistor

Author

Krishnan, Radha, Biswas, Sangram, Hsueh, Yu-Ling, Ma, Hongyang, Rahman, Rajib, and Weber, Bent

Abstract

Spins confined to atomically thin semiconductors are being actively explored as quantum information carriers. In transition metal dichalcogenides (TMDCs), the hexagonal crystal lattice gives rise to an additional valley degree of freedom with spin-valley locking and potentially enhanced spin life and coherence times. However, realizing well-separated single-particle levels and achieving transparent electrical contact to address them has remained challenging. Here, we report well-defined spin states in a few-layer MoS2transistor, characterized with a spectral resolution of ∼50 μeV at Tel= 150 mK. Ground state magnetospectroscopy confirms a finite Berry-curvature induced coupling of spin and valley, reflected in a pronounced Zeeman anisotropy, with a large out-of-plane g-factor of g⊥≃ 8. A finite in-plane g-factor (g∥≃ 0.55–0.8) allows us to quantify spin-valley locking and estimate the spin–orbit splitting 2ΔSO∼ 100 μeV. The demonstration of spin-valley locking is an important milestone toward realizing spin-valley quantum bits.

Published

2023

4. Two-Dimensional CH3NH3PbI3Perovskite: Synthesis and Optoelectronic Application

Author

Liu, Jingying, Xue, Yunzhou, Wang, Ziyu, Xu, Zai-Quan, Zheng, Changxi, Weber, Bent, Song, Jingchao, Wang, Yusheng, Lu, Yuerui, Zhang, Yupeng, and Bao, Qiaoliang

Abstract

Hybrid organic–inorganic perovskite materials have received substantial research attention due to their impressively high performance in photovoltaic devices. As one of the oldest functional materials, it is intriguing to explore the optoelectronic properties in perovskite after reducing it into a few atomic layers in which two-dimensional (2D) confinement may get involved. In this work, we report a combined solution process and vapor-phase conversion method to synthesize 2D hybrid organic–inorganic perovskite (i.e., CH3NH3PbI3) nanocrystals as thin as a single unit cell (∼1.3 nm). High-quality 2D perovskite crystals have triangle and hexagonal shapes, exhibiting tunable photoluminescence while the thickness or composition is changed. Due to the high quantum efficiency and excellent photoelectric properties in 2D perovskites, a high-performance photodetector was demonstrated, in which the current can be enhanced significantly by shining 405 and 532 nm lasers, showing photoresponsivities of 22 and 12 AW–1with a voltage bias of 1 V, respectively. The excellent optoelectronic properties make 2D perovskites building blocks to construct 2D heterostructures for wider optoelectronic applications.

Published

2016