Dynamical control of random telegraph noise in magnetic tunnel junctions

Rapid random telegraph noise (RTN) in magnetic tunnel junctions (MTJs) is an important figure of merit for probabilistic computing applications. However, the interactions between the macrospin and spin waves with finite wave numbers reduce the RTN attempt frequency. We theoretically show that mode-selective heating and cooling can substantially tune the RTN frequency. We propose a nonlinear cooling mechanism that accelerates the switching dynamics. We outline experimental pathways to characterize the physics of nonlinear effects on RTN and to maximize the operation speed of MTJ-based probabilistic computing.