Coherent control of ultrafast optical four-wave mixing with two-colorω−3ωlaser pulses

Abstract

A theoretical investigation on the quantum control of optical coherent four-wave mixing interactions in two-level systems driven by two intense synchronized femtosecond laser pulses of central angular frequencies $\omega$ and $3\omega$ is reported. By numerically solving the full Maxwell-Bloch equations beyond the slowly-varying envelope and rotating-wave approximations in the time domain, the nonlinear coupling to the optical field at frequency $5\omega$ is found to depend critically on the initial relative phase $\phi$ of the two propagating pulses; the coupling is enhanced when the pulses interfere constructively in the center ($\phi=0$), while it is nearly suppressed when they are out of phase ($\phi=\pi$). The tuning of the initial absolute phase of the different frequency components of synchronously propapagating $\omega$-$3\omega$ femtosecond pulses can serve as a means to control coherent anti-Stokes Raman scattering (CARS) processes.