Nuclear Spin-Mediated Relaxation Mechanisms of the VB- Center in hBN

Abstract

The negatively charged boron vacancy VB- defect in hexagonal boron nitride (hBN) has recently emerged as a promising spin qubit for sensing due to its high-temperature spin control and versatile integration into van der Waals structures. While extensive experiments have explored their coherence properties, much less is known about the spin relaxation time T1 and its control-parameter dependence. In this work, we develop a parameter-free spin dynamics model based on the cluster-expansion technique to investigate T1 relaxation mechanisms at low temperature. Our results reveal that the VB- center constitutes a strongly coupled electron spin-nuclear spin core, which necessitates the inclusion of the coherent dynamics and derived memory effects of the three nearest-neighbor nitrogen nuclear spins. Using this framework, this work closely reproduces the experimentally observed T1 time at B = 90\,G and further predicts the T1 dependence on external magnetic field in the 0 B 2000\,G interval, when the spin relaxation is predominantly driven by electron-nuclear and nuclear-nuclear flip-flop processes mediated by hyperfine and dipolar interactions. This study establishes a reliable and scalable approach for describing T1 relaxation in VB- centers and offers microscopic insights to support future developments in nuclear-spin-based quantum technologies.