Lightwave Electronic Harmonic Frequency Mixing

Frequency mixers are fundamental building blocks in many electronic systems. They enable frequency conversion for signal detection and processing. While conventional electronic frequency mixers operate in the GHz or at best in the THz frequency range, a compact and scalable petahertz-scale electronic frequency mixer would enable practical field-resolved optical signal processing and readout without the need for nonlinear optical elements. We used nanoscale antenna structures to experimentally demonstrate electronic harmonic mixing beyond 0.350 PHz. Through this harmonic mixing process, we demonstrate time-domain sampling of optical field waveforms spanning more than one octave of bandwidth. The high nonlinearity of the devices enabled field-resolved detection of spectral content outside of that contained within the local oscillator, greatly extending the range of detectable frequencies compared to conventional heterodyning techniques. We anticipate these devices to provide compact, PHz-scale solid-state detection for integration with emerging technologies such as compact frequency combs, optical waveform synthesizers, and compact timing systems. Our work has important implications for various fields such as chemistry, physics, material science, and biology, where PHz signals exhibiting femtosecond-scale dynamics are of great interest for spectroscopic analysis or imaging.