TY - JOUR
T1 - Optical super-resolution imaging
T2 - A review and perspective
AU - Aflalo, Kobi
AU - Gao, Peng
AU - Trivedi, Vismay
AU - Sanjeev, Abhijit
AU - Zalevsky, Zeev
N1 - Publisher Copyright:
© 2024
PY - 2024/12
Y1 - 2024/12
N2 - In this comprehensive review, we delve into super-resolution optical imaging techniques and their diverse applications. Our primary focus is on linear optics super-resolution methods, encompassing a wide array of concepts ranging from time multiplexing, ptychography, and deep learning-based microscopy to compressive sensing and random phase encoding techniques. Additionally, we explore compressed sensing, non-spatial resolution improvement, and sparsity-based geometric super-resolution. Furthermore, we investigate various methods based on field of view, wavelength, coherence, polarization, gray level, and code division multiplexing, as well as localization microscopy. Our review extends to stimulated emission depletion microscopy via pump-probe super-resolution techniques, providing a detailed analysis of their working applications. We then shift our attention to near-field scanning optical microscopy, discussing its principles and applications in various fields. Recent techniques such as Microsphere-assisted microscopy, Airyscan, mean-shift super-resolution, photothermal relaxation localization microscopy, and a novel structured illumination-based super-resolution technique enables tomography of semi-transparent samples by investigating their refractive index thus providing a 3D map of the samples. Moreover, we examine the concept of super-resolution in a nonlinear medium, highlighting its unique characteristics and potential benefits. Finally, we discuss the future perspectives and trends of super-resolution optical imaging, offering insights into its potential evolution and impact on the field.
AB - In this comprehensive review, we delve into super-resolution optical imaging techniques and their diverse applications. Our primary focus is on linear optics super-resolution methods, encompassing a wide array of concepts ranging from time multiplexing, ptychography, and deep learning-based microscopy to compressive sensing and random phase encoding techniques. Additionally, we explore compressed sensing, non-spatial resolution improvement, and sparsity-based geometric super-resolution. Furthermore, we investigate various methods based on field of view, wavelength, coherence, polarization, gray level, and code division multiplexing, as well as localization microscopy. Our review extends to stimulated emission depletion microscopy via pump-probe super-resolution techniques, providing a detailed analysis of their working applications. We then shift our attention to near-field scanning optical microscopy, discussing its principles and applications in various fields. Recent techniques such as Microsphere-assisted microscopy, Airyscan, mean-shift super-resolution, photothermal relaxation localization microscopy, and a novel structured illumination-based super-resolution technique enables tomography of semi-transparent samples by investigating their refractive index thus providing a 3D map of the samples. Moreover, we examine the concept of super-resolution in a nonlinear medium, highlighting its unique characteristics and potential benefits. Finally, we discuss the future perspectives and trends of super-resolution optical imaging, offering insights into its potential evolution and impact on the field.
KW - Optical diffraction limit
KW - Optical imaging
KW - Optical super-resolution
UR - http://www.scopus.com/inward/record.url?scp=85202756979&partnerID=8YFLogxK
U2 - 10.1016/j.optlaseng.2024.108536
DO - 10.1016/j.optlaseng.2024.108536
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AN - SCOPUS:85202756979
SN - 0143-8166
VL - 183
JO - Optics and Lasers in Engineering
JF - Optics and Lasers in Engineering
M1 - 108536
ER -