Jeng-Yuan Tsai1,Jinbo Pan2,Hsin Lin3,Arun Bansil4,Qimin Yan1
Temple University1,Chinese Academy of Sciences2,Academia Sinica3,Northeastern University4
Jeng-Yuan Tsai1,Jinbo Pan2,Hsin Lin3,Arun Bansil4,Qimin Yan1
Temple University1,Chinese Academy of Sciences2,Academia Sinica3,Northeastern University4
Quantum bit as the heart of quantum information technology brings unprecedented capability of computation that is expected to transform science and society in unimaginable ways. While solid-state defects in three-dimensional hosts such as diamond-NV centers have demonstrated as a promising qubit, two-dimensional (2D) materials offer a new paradigm for the realization of patterned qubit fabrication and operation at room temperature. Using high-throughput atomistic simulations and a symmetry-based hypothesis, we identify six neutral anion-antisite defects in transition metal dichalcogenide (TMD) monolayers that host a paramagnetic triplet ground state. The optical transitions and triplet-singlet intersystem crossings in the qubit providing a complete cycle for initialization, manipulation and redout of the qubit are discussed. As an illustrative example, the operational principles of the antisite qubit in WS<sub>2</sub> are discussed in details. The key characters of host materials that give rise to defects with a triplet ground state are discussed, which suggests a feasible strategy for continued discovery of promising defect qubits in diverse classes of 2D materials. Our study opens a new pathway for creating scalable and controllable spin qubits in 2D TMDs.