Clara Dehman, José A. Pons

The chiral magnetic effect (CME), a macroscopic manifestation of the quantum chiral anomaly, induces currents along magnetic field lines, facilitating mutual conversion between chiral asymmetry and magnetic helicity. Although the finite electron mass suppresses chiral asymmetry through spin-flip processes, we demonstrate that the CME remains effective and plays a significant role in the magnetic field evolution of magnetars. The magnetic helicity acts as a persistent internal source of chiral asymmetry, which mediates the redistribution of magnetic energy across spatial scales, without requiring an external energy source. Focusing on the neutron star crust, we show that this mechanism reshapes the magnetic field configuration inherited at birth and, within a hundred years, amplifies both toroidal and poloidal large-scale dipolar components (relevant for spin-down) up to $10^{14}$ G at the expense of small-scale structures. Our results offer a microphysical mechanism, alternative to traditional hydrodynamic dynamo models, establishing a new framework for understanding magnetar field dynamics.