Standard Standard

Unibody microscope objective tipped with a microsphere: design, fabrication, and application in subwavelength imaging. / Yan, Bing; Song, Yang; Yang, Xibin et al.
In: Applied Optics, Vol. 59, No. 8, 10.03.2020, p. 2641-2648.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

APA

CBE

MLA

VancouverVancouver

Yan B, Song Y, Yang X, Xiong D, Wang J. Unibody microscope objective tipped with a microsphere: design, fabrication, and application in subwavelength imaging. Applied Optics. 2020 Mar 10;59(8):2641-2648. doi: 10.1364/AO.386504

Author

Yan, Bing ; Song, Yang ; Yang, Xibin et al. / Unibody microscope objective tipped with a microsphere: design, fabrication, and application in subwavelength imaging. In: Applied Optics. 2020 ; Vol. 59, No. 8. pp. 2641-2648.

RIS

TY - JOUR

T1 - Unibody microscope objective tipped with a microsphere: design, fabrication, and application in subwavelength imaging

AU - Yan, Bing

AU - Song, Yang

AU - Yang, Xibin

AU - Xiong, Daxi

AU - Wang, James

PY - 2020/3/10

Y1 - 2020/3/10

N2 - Microsphere-based subwavelength imaging technique was first demonstrated in 2011. After nearly a decade of efforts, such technique has spawned numerous interests in fields such as laser nano-machining, imaging, sensing, and biological detection. For wider industrial-scale application of the technique, a robust and low-cost objective lens incorporating a microsphere lens is highly desired and sought by many researchers. In this work, we demonstrate a unibody microscope objective lens formed by tipping a high-index microsphere onto a plano-convex lens and subsequently fitting them into a conventional objective lens.We call this the plano-convex-microsphere (PCM) objective, which resembles the appearance and operation of an ordinary microscope objective while providing super-resolving power in discerning subwavelength 100 nm features (=4.7) in air and far-field conditions. The imaging performance of thePCMobjective, along with the working distance, has been systematically investigated. It has a calibrated resolution of =3 in the far field, a numerical aperture of 1.57, and a working distance of 3.5 m. With the assistance of a scanning process, larger-area imaging is realized. ThePCMobjective can be easily adapted to existing microscope systems and is appealing for commercialization.

AB - Microsphere-based subwavelength imaging technique was first demonstrated in 2011. After nearly a decade of efforts, such technique has spawned numerous interests in fields such as laser nano-machining, imaging, sensing, and biological detection. For wider industrial-scale application of the technique, a robust and low-cost objective lens incorporating a microsphere lens is highly desired and sought by many researchers. In this work, we demonstrate a unibody microscope objective lens formed by tipping a high-index microsphere onto a plano-convex lens and subsequently fitting them into a conventional objective lens.We call this the plano-convex-microsphere (PCM) objective, which resembles the appearance and operation of an ordinary microscope objective while providing super-resolving power in discerning subwavelength 100 nm features (=4.7) in air and far-field conditions. The imaging performance of thePCMobjective, along with the working distance, has been systematically investigated. It has a calibrated resolution of =3 in the far field, a numerical aperture of 1.57, and a working distance of 3.5 m. With the assistance of a scanning process, larger-area imaging is realized. ThePCMobjective can be easily adapted to existing microscope systems and is appealing for commercialization.

U2 - 10.1364/AO.386504

DO - 10.1364/AO.386504

M3 - Article

VL - 59

SP - 2641

EP - 2648

JO - Applied Optics

JF - Applied Optics

SN - 1559-128X

IS - 8

ER -