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Diffraction of light microscope3/2/2024 Our completely novel quantum resources will support quantum research and development and act as a new pair of ‘glasses’ for a closer look at the weirdness of the nanoscale quantum world.In a recently published paper in Light: Science & Applications, a team of researchers from Yonsei University, Seoul, Republic of Korea, have proposed an innovative solution to these challenges 8. Boiko concludes: "We not only improved microscopy resolution but delivered a wonderful new set of tools for light generation, detection, and processing. The tools should spur on discovery in numerous fields with impact on citizens ranging from personalised precision healthcare to fast communications through secure quantum networks. This unprecedented capability is further advanced by the unplanned demonstration of quantum-classical photon discrimination, achieved by detecting correlated biphoton arrivals based on their de Broglie wavelength and utilising a slit mask to transmit only non-classical photon states.” Perenzoni summarises: “SUPERTWIN’s microscope prototype exploiting non-classical entangled photons enables imaging that overcomes the Rayleigh resolution limit. Finally, a quantum reconstruction algorithm puts the pieces of the puzzle together, iteratively improving the resolution. Perenzoni notes that the team is excited to share this important outcome with the scientific community and has already received many requests for evaluation in Europe and abroad. A high-resolution quantum image sensor accomplishes ultrafast single-photon detection for the correlation of N-partite entangled states. "A theoretical framework supported the development of a solid-state source of non-classical light and non-classically correlated light states,” explains project scientific and technical coordinator Dmitri Boiko of the Swiss Centre for Electronics and Microtechnology. SUPERTWIN scientists needed a device to produce the separate but entangled photons, a system to detect the single photons as they are reflected, and a mathematical way to process their characteristics and link them back to those of the object of interest. For example, with 5 entangled photons at 400 nm wavelength, we could theoretically obtain 40 nm resolution.” Generating the pieces and making the puzzle N entangled photons with wavelength λ collectively behave as a single entity of wavelength λ/N (called the de Broglie wavelength) and consequently the Rayleigh limit becomes λ/2N. Project coordinator Matteo Perenzoni of the Fondazione Bruno Kessler explains: “Super-twinning photon states, also called N-partite entangled states, are ensembles of N photons of a given wavelength that share physical quantum properties you cannot describe one without considering the others. To overcome this barrier, SUPERTWIN harnessed the phenomenon of entangled states. For example, a flu virus at 80-120 nanometres is a blur when viewed with conventional light microscopy. The Rayleigh limit, the optical barrier or intuitively the smallest discernible difference, is defined as λ/2 for any given wavelength this means our ‘classical’ best is about 200 nanometres. The smallest wavelength (λ) of visible light that we can see is 400 nanometres (nm), corresponding to violet light. The EU-funded SUPERTWIN project has exploited entangled photons in a pioneering light microscope that overcomes the diffraction barrier, opening a new window on the quantum world. The ‘diffraction barrier’ refers to the resolution limit of optical imaging systems imposed by diffraction, the spreading of light waves as they bend around material or pass through a narrow aperture – and a nanoscale sample is like a small aperture. Despite tremendous technological developments improving image quality, optical microscopy faces resolution limitations imposed by physical laws.
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