Temperature dependence of quasi-localized phonons-mediated non-Markovianity dynamics of SiV- centers in diamond

Abstract

Here we investigate the temperature-dependent non-Markovian dynamics of the SiV- center in diamond, focusing on the roles of low- and high-frequency quasi-localized phonon modes. Low-frequency phonons exhibit stronger electron-phonon coupling, leading to long-lived dephasing rate, while high-frequency phonons induce rapid attenuation of oscillatory dephasing rate facilitating a persistent memory effect. The non-Markovianity measure NC shows memory effects persisting at low temperatures but diminishing at high temperatures due to enhanced damping. The temperature dependence of NC follows a monotonic decay, from which a transition temperature TNM=110 K is determined. These results highlight the interplay between phonon activation and damping in shaping quantum coherence, offering insights for optimizing solid-state quantum systems.