Litcius/Paper detail

Ultra-CEP-stable single-cycle pulses at 2.2  µm

Maciej Kowalczyk, Nathalie Nagl, Philipp Steinleitner, Nicholas Karpowicz, Vladimir Pervak, Aleksander Głuszek, Arkadiusz Hudzikowski, Ferenc Krausz, Ka Fai Mak, Alexander Weigel

2023Optica38 citationsDOIOpen Access PDF

Abstract

Single-cycle optical pulses with controllable carrier-envelope phase (CEP) form the basis to manipulate the nonlinear polarization of matter on a sub-femtosecond time scale. Moreover, nonlinear light–matter energy exchange and frequency conversion processes benefit from longer, infrared wavelengths. We report a highly stable source of 6.9-fs, single-cycle pulses at 2.2 µm, based on a directly diode-pumped Cr:ZnS oscillator with 22.9-MHz repetition rate. Extreme spectral broadening of the oscillator output to a super-octave bandwidth (1.1–3.1 µm) is achieved in a single rutile (TiO 2 ) plate. Excellent agreement with simulations provides a precise understanding of the underlying nonlinear pulse propagation. A comprehensive investigation of alternative broadening materials and additional simulations single out the exceptional broadening in TiO 2 due to the favorable interplay of self-focusing, and plasma formation accompanied by self-phase modulation and self-compression. Unprecedented reproducibility of the single-cycle waveforms is ensured by a unique combination of active CEP stabilization with a residual CEP jitter of only 5.9 mrad (0.1 Hz to 11.45 MHz) and a relative intensity noise of 0.036% (0.1 Hz to 1 MHz). The new single-cycle source permits efficient downconversion to the mid-infrared by cascaded intra-pulse difference frequency generation, giving access to sub-femtosecond manipulation of electric currents in low-bandgap materials with an unprecedented degree of control.

Topics & Concepts

FemtosecondLaserMaterials scienceOpticsCarrier-envelope phaseOptoelectronicsAttosecondPhysicsUltrashort pulseLaser-Matter Interactions and ApplicationsAdvanced Fiber Laser TechnologiesSolid State Laser Technologies