Anomalous Phase-Coherence Scaling in a Quantum-Critical Dirac Semimetal

Abstract

We have investigated the weak antilocalization (WAL) in the pressurized Dirac semimetal α-(BEDT-TTF)2I3 across a correlation-driven quantum phase transition to a charge-ordered insulating state and evaluated the phase coherence length Lφ and its temperature scaling under various pressures from the low-temperature magnetoconductivity. In the high-pressure regime, the system exhibits the conventional two-dimensional dephasing behavior (Lφ T-p with p ≈ 1/2), characteristic of electron-electron scattering in diffusive conductors. As the pressure approaches the critical pressure (Pc 1.2 GPa), the temperature exponent is suppressed to p 0.3, while Lφ remains large (700-800 nm at 0.5 K). This anomalous scaling suggests nontrivial inelastic scattering associated with Dirac electrons near the quantum critical point. The persistence of WAL across the transition supports a gapless or nearly gapless quantum phase transition.