Shaping Ultrafast Pulses for Enhanced Resonant Nonlinear Interactions

Coherent control with shaped ultrafast pulses is a powerful approach for steering nonlinear light-matter interactions. Previous studies in quantum control have shown that, beyond transform-limited pulses, those with antisymmetric spectral phases can drive nonresonant multiphoton transitions with comparable efficiency. However, in resonant multiphoton transitions, the material's spectral-phase response introduces dispersion that degrades nonlinear efficiency. Pre-shaping the pulse to compensate for the material's impulse response can restore and enhance nonlinear interactions beyond the transform-limited case. Yet, is this the only spectral phase that can yield such enhancement? Here, we study sub-10 fs single-pulse four-wave mixing in resonant plasmonic nanostructures using arctangent spectral-phase-shaped pulses. We uncover two distinct enhancement regimes: one compensating for material dispersion, and a counterintuitive regime where the arctangent phase induces an antisymmetric polarization response, driving constructive multiphoton pathway interference. Our theoretical analysis provides clear physical explanation for both phenomena. Notably, it predicts that both enhancement mechanisms scale exponentially with harmonic order, offering a powerful strategy for dramatically enhancing high-order harmonic generation in resonant systems.