Abstract
Recent experiments demonstrate precise control over coherently excited phonon modes using high-intensity terahertz lasers, opening new pathways towards dynamical, ultrafast design of magnetism in functional materials. In this work, we put forward a coupling mechanism based on electron-nuclear quantum geometry. This effect is rooted in the phase accumulation of the electronic wavefunction under a circular evolution of nuclear coordinates. An excitation pulse then induces a transient level splitting between electronic orbitals that carry angular momentum. When converted to effective magnetic fields, values on the order of tens of Teslas are easily reached.
