Quantum spectroscopy: How 'squeezed light' can boost environmental sensing

An integrated silicon photonic chip and a red laser pumped nonlinear interferometer used for methane sensing

An integrated silicon photonic chip for methane sensing, left. Right:A red laser pumped nonlinear interferometer used for methane sensing. (Pictures courtesy of Dr Arthur Cardoso, QET Labs, University of Bristol)

Combining quantum mechanics and photonics could greatly enhance sensing systems used in environmental monitoring, explains the University of Bristol’s Dr Alex Clark

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Quantum spectroscopy: How 'squeezed light' can boost environmental sensing

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