Room Temperature Microsecond Coherence of Silicon Dangling Bonds

Abstract: Paramagnetic point defects in silicon provide qubits that could open up pathways towards silicon-technology based, low-cost, room-temperature (RT) quantum sensing. The silicon dangling bond (db) is a natural candidate, given its sub-nanometer localization and direct involvement in spin-dependent charge-carrier recombination, allowing for electrical spin readout. In crystalline silicon, however, rapid loss of db spin-coherence at RT due to free-electron trapping, strongly limits quantum applications. In this work, by combining density-functional theory and multifrequency (100 MHz-263 GHz) pulsed electrically detected magnetic resonance spectroscopy, we show that upon electron capture, dbs in a hydrogenated amorphous silicon matrix form metastable spin pairs in a well-defined quasi two-dimensional (2D) configuration. Although highly localized, these entangled spin pairs exhibit nearly vanishing intrinsic dipolar and exchange coupling. The formation of this magic-angle-like configuration involves a >0.3 eV energy relaxation of a trapped electron, stabilizing the pair. This extends RT spin coherence times into the microsecond range in silicon required for a future spin-based quantum sensing technology.