Phys. Rev. B 85, 165433 (2012)
Nonlinear Zeeman splitting of neutral excitons is observed in composition-engineered InxGa1−xAs self-assembled quantum dots, and its microscopic origin is explained. Eight-band k·p simulations, performed using realistic dot parameters extracted from cross-sectional scanning tunneling microscopy measurements, reveal that a quadratic contribution to the Zeeman energy originates from a spin-dependent mixing of heavy- and light-hole orbital states in the dot. The dilute In composition (x<0.35) and large lateral size (40–50 nm) of the quantum dots investigated are shown to strongly enhance the nonlinear contribution to the excitonic Zeeman gap, providing a blueprint to enhance such magnetic nonlinearities via growth engineering of the quantum dots.