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Quantum-enhanced time-domain spectroscopy

Dionysis Adamou, Lennart Hirsch, Taylor Shields, Seungjin Yoon, Adetunmise C. Dada, Jonathan Weaver, Daniele Faccio, Marco Peccianti, Lucia Caspani, Matteo Clerici

2025Science Advances12 citationsDOIOpen Access PDF

Abstract

The time-resolved detection of mid- to far-infrared electric fields absorbed and emitted by molecules is among the most sensitive spectroscopic approaches and has the potential to transform sensing in fields such as security screening, quality control, and medical diagnostics. However, the sensitivity of the standard detection approach, which relies on encoding the far-infrared electric field into amplitude modulation of a visible or near-infrared probe laser pulse, is limited by the shot noise of the latter. This constraint cannot be overcome without using a quantum resource. Here, we show that this constraint can be overcome using a two-mode squeezed state. Quantum-correlated ultrashort pulses, generated by parametric down-conversion, enhance the sensitivity of far-infrared detection beyond the classical limit, achieving a twofold reduction in measured noise. This advancement paves the way for further development of ultrafast quantum metrology, moving toward quantum-enhanced time-resolved electric field spectroscopy with sensitivities beyond the standard quantum limit.

Topics & Concepts

Ultrashort pulseQuantum metrologyQuantum limitPhysicsQuantumQuantum sensorSensitivity (control systems)SpectroscopyNoise (video)Quantum noiseOpticsLaserElectric fieldQuantum technologyComputer scienceOpen quantum systemQuantum mechanicsElectronic engineeringImage (mathematics)EngineeringArtificial intelligenceSpectroscopy and Quantum Chemical StudiesSpectroscopy Techniques in Biomedical and Chemical ResearchSpectroscopy and Laser Applications
Quantum-enhanced time-domain spectroscopy | Litcius