Attosecond Control of Squeezed Light

TL;DR

This paper demonstrates attosecond control over the degree and type of squeezed light generated in nonlinear dielectrics by manipulating the nonlinear response with ultrafast laser pulses, enabling advanced quantum information applications.

Contribution

It introduces a method to modulate the nonlinear response in dielectrics on attosecond timescales to control squeezed light properties, including switching between amplitude and phase squeezing.

Findings

Controlled the nonlinear response with sub-cycle phase delay.

Achieved switching from amplitude to phase squeezing.

Measured quantum correlations across frequency modes.

Abstract

Squeezed light has revolutionized quantum metrology by enhancing interferometry for sensitive applications such as the detection of gravitational waves. Squeezed light has also played a pivotal role in quantum information science with numerous applications in quantum computing and communication. Previously, squeezed light has been primarily generated using nonlinear optical interactions, where control of the degree of squeezing was possible by tuning the nonlinearity of the generating medium using suitable material engineering. Here, we modulate the third-order nonlinear response in dielectrics with strong ultrafast laser fields to control the degree of squeezing on attosecond time scales. We demonstrate the ability to change the ultrafast squeezed light generated in the nonlinear process from amplitude-squeezed to phase-squeezed by controlling the strong-field-driven nonlinear response of the material through a sub-cycle phase delay between the input femtosecond laser pulses. The squeezing of quantum noise is measured using a frequency-resolved balanced homodyne detection scheme capable of extracting the field quadratures in different frequency modes simultaneously. Using this frequency-resolved measurement we extract the complete coherency matrix containing the quantum correlations between field quadratures across different frequency modes of the femtosecond squeezed light pulse. These results have major implications for the development of quantum light sources with unprecedented levels of control over quadrature squeezing, for applications in multimode quantum information processing, and for measuring transient quantum matter correlations via transduction to quantum field correlations in an ultrafast light-matter interaction.