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Abstract

In this paper, we investigate flux-flow instability (FFI) in a superconducting single-crystal titanium nitride (TiN) film with negligible volume pinning. By studying the critical current density in 12-nm thick TiN strips of varying widths, we accurately identify the experimental parameters at which the FFI regime occurs. A comprehensive analysis of critical velocity measurements allows us to determine the quasiparticle energy relaxation time, $\tau_E$. By comparing our results with the $\tau_E$ values obtained from other experimental methods, we gain insight into the dominant microscopic process that governs quasiparticle relaxation within the vortex core in TiN. This mechanism is driven by an increase in quasiparticle temperature relative to phonons, rather than by quasiparticles leaving the core. Our findings indicate that $\tau_E$ can be accurately determined through FFI measurements.