The technique uses entangled photons to overcome the limitations of conventional holographic approaches
Taking advantage of collective quantum effects has enabled the so-called first quantum revolution in the 20th century for technologies such as nuclear magnetic resonance spectroscopy, magnetic resonance imaging, and the development of transistors, LEDs, solar panels, and lasers. Today, amid the second quantum revolution new sensing schemes offer higher sensitivities and better resolution thanks to the possibility to detect and control individual quantum states in microscopic systems like atoms, quantum dots, or color centers.
Carlos Lee speaks to Mike Powell, managing partner of Renevo Capital Limited, an investment bank specialising in photonics and semiconductors
Optical benches at Politecnico di Milano, the general coordinator of the Crimson project. Credit: Politecnico di Milano
It can take a village to bring a medical photonics device to market, Benjamin Skuse discovers
Image credit: Aris-Tect Group/Shutterstock.com
We round-up the latest products and solutions in the single photon counting space.
Image credit: Yury Zap/Shutterstock.com
A look at the commercial offerings of the main players in freeform optics.
How automotive companies can choose the right lidar technology for their applications, by Gemma Church
Credit: KLA
Here we highlight some of the initiatives working to engage and train young people in optics and photonics
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Raman spectroscopy has huge potential for use in medicine, as David Stuart finds out
Fabless start-up Scintil Photonics has raised €13.5m for its laser-integrated silicon chips. We speak to co-founder Sylvie Menezo
