Quantum light microscopy

Quantum light microscopy

Much of our progress in understanding microscale biology has been powered by advances in microscopy. For instance, super-resolution microscopes allow the observation of biological structures at near-atomic-scale resolution, while multi-photon microscopes allow imaging deep into tissue. However, biol...

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Bibliographic Details
Published in:Contemporary physics Vol. 64; no. 3; pp. 169 - 193
Main Authors: Bowen, W. P., Chrzanowski, Helen M., Oron, Dan, Ramelow, Sven, Tabakaev, Dmitry, Terrasson, Alex, Thew, Rob
Format: Journal Article
Language:English
Published: London Taylor & Francis 03-07-2023
Taylor & Francis Ltd
Subjects:
biological imaging
entanglement
Image enhancement
Image resolution
Light microscopy
Microscopes
Microscopy
nonlinear microscopy
Optical microscopy
Photon scatter
Photons
quantum correlations
Quantum entanglement
Quantum mechanics
Quantum microscopy
quantum technologies
Scattering cross sections
super-resolution imaging
Wavelengths
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Description
Summary:Much of our progress in understanding microscale biology has been powered by advances in microscopy. For instance, super-resolution microscopes allow the observation of biological structures at near-atomic-scale resolution, while multi-photon microscopes allow imaging deep into tissue. However, biological structures and dynamics still often remain out of reach of existing microscopes, with further advances in signal-to-noise, resolution and speed needed to access them. In many cases, the performance of microscopes is now limited by quantum effects – such as noise due to the quantisation of light into photons or, for multi-photon microscopes, the low cross-section of multi-photon scattering. These limitations can be overcome by exploiting features of quantum mechanics such as entanglement. Quantum effects can also provide new ways to enhance the performance of microscopes, such as new super-resolution techniques and new techniques to image at difficult to reach wavelengths. This review provides an overview of these various ways in which quantum techniques can improve microscopy, including recent experimental progress. It seeks to provide a realistic picture of what is possible, and what the constraints and opportunities are.
ISSN:0010-7514
1366-5812
DOI:10.1080/00107514.2023.2292380