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Enhanced resolution beyond the Abbe diffraction limit with wavelength-scale solid immersion lenses.
Mason, Daniel R,Jouravlev, Mikhail V,Kim, Kwang S Optical Society of America 2010 Optics letters Vol.35 No.12
<P>The solid immersion lens (SIL) is a well-developed near-field optical device for imaging and data storage. Recent experiments have demonstrated high-quality imaging beyond the diffraction limit by nanoscale lenses in an SIL-type implementation [Nature 460, 498 (2009)]; we call these nSIL. A question arises as to what resolution is obtainable with an nSIL. From full three-dimensional, finite-difference time-domain calculations, we demonstrate that the FWHM of the focal spot of an objective-lens-nSIL system can be reduced by greater than 25% compared to a regular macroscopic SIL.</P>
Near-field focusing and magnification through self-assembled nanoscale spherical lenses
Lee, Ju Young,Hong, Byung Hee,Kim, Woo Youn,Min, Seung Kyu,Kim, Yukyung,Jouravlev, Mikhail V.,Bose, Ranojoy,Kim, Keun Soo,Hwang, In-Chul,Kaufman, Laura J.,Wong, Chee Wei,Kim, Philip,Kim, Kwang S. Macmillan Publishers Limited. All rights reserved 2009 Nature Vol.460 No.7254
It is well known that a lens-based far-field optical microscope cannot resolve two objects beyond Abbe’s diffraction limit. Recently, it has been demonstrated that this limit can be overcome by lensing effects driven by surface-plasmon excitation, and by fluorescence microscopy driven by molecular excitation. However, the resolution obtained using geometrical lens-based optics without such excitation schemes remains limited by Abbe’s law even when using the immersion technique, which enhances the resolution by increasing the refractive indices of immersion liquids. As for submicrometre-scale or nanoscale objects, standard geometrical optics fails for visible light because the interactions of such objects with light waves are described inevitably by near-field optics. Here we report near-field high resolution by nanoscale spherical lenses that are self-assembled by bottom-up integration of organic molecules. These nanolenses, in contrast to geometrical optics lenses, exhibit curvilinear trajectories of light, resulting in remarkably short near-field focal lengths. This in turn results in near-field magnification that is able to resolve features beyond the diffraction limit. Such spherical nanolenses provide new pathways for lens-based near-field focusing and high-resolution optical imaging at very low intensities, which are useful for bio-imaging, near-field lithography, optical memory storage, light harvesting, spectral signal enhancing, and optical nano-sensing.