Nonlinear Shaping in the Picosecond Gap

Lightwave pulse shaping in the picosecond regime has remained unaddressed because it resides beyond the limits of state-of-the-art techniques, either due to its inherently narrow spectral content or fundamental speed limitations in electronic devices. The so-called picosecond shaping gap hampers progress in ultrafast photoelectronics, health and medical technologies, energy and material sciences, and many other fundamental sciences. We report on a novel nonlinear method to simultaneously frequency-convert and adaptably shape the envelope of light wavepackets in the picosecond regime by balancing spectral engineering and nonlinear conversion in solid-state nonlinear media, without requiring active devices. The versatility of our methodology is captured computationally by generating a multitude of temporally shaped pulses via various nonlinear conversion chains and initial conditions. Additionally, we experimentally demonstrate this framework by producing picosecond-shaped, ultra-narrowband, near-transform limited pulses from broadband, femtosecond input pulses. Our proofs provide an avenue toward arbitrary and programmable lightwave shaping for GHz-to-THz photoelectronic sciences and technologies.