Nanoscale optical microscopy in the vectorial focusing regime

Serrels, K. A.; Ramsay, E.; Warburton, Richard J.; Reid, Derryck T.

doi:10.1038/nphoton.2008.29

Cited by 86 publications

(35 citation statements)

References 15 publications

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“…The transverse electric beam (TE1) has a central lobe with a width (harmonic mean over all orientations) even narrower than for the radially polarized case. The beam cross-section is asymmetric, but it has been demonstrated that multiple images can be used to give resolution equivalent to the minor axis [28]. Alternatively, an axially symmetric beam with substantially circularly polarization can be generated using illumination that is azimuthally polarized with a phase singularity, giving an axially symmetric central lobe narrower than that for radial polarization.…”

Section: Discussionmentioning

confidence: 99%

Bessel beams: Effects of polarization

Sheppard¹,

Rehman²,

Balla³

et al. 2009

Optics Communications

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Section: Discussionmentioning

confidence: 99%

Bessel beams: Effects of polarization

Sheppard¹,

Rehman²,

Balla³

et al. 2009

Optics Communications

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“…This was attributed to a new ability to perform systematic axial scanning and thus an ability to localise the focus of the beam in the component layer of the chip more accurately. Recently, we have reported SIL-enhanced polarization-sensitive imaging which, under certain conditions, surpasses conventional scalar diffraction limited performance as described by Sparrow's resolution criteria [3]. Under such SIL-induced extreme NA conditions the resulting focal-plane intensity distribution is strongly asymmetric and cannot be described correctly by scalar diffraction theory because the polarization direction of the incident light must be taken into account.…”

Section: Solid Immersion Lens Microscopy Using Tobic Imagingmentioning

confidence: 97%

“…Subsequently, we have demonstrated, using imaging at 1530 nm, optical resolutions approaching ~100 nm [3] by implementing TOBIC microscopy using an s-SIL. We used the s-SIL modality because we are interested in resolving circuit features located around 100 µm below the backside surface of the silicon die.…”

Section: Solid Immersion Lens Microscopy Using Tobic Imagingmentioning

confidence: 99%

“…Since its invention, the SIL has been exploited in several nanoscale technologies, including semiconductor integrated-circuit (IC) inspection [1][2][3], nanoscale spectroscopy [4,5], optical data storage [6,7] and photolithography [8], yet the benefits the SIL has introduced in these fields have received poor coverage. Therefore, in this paper we aim to review the theoretical aspects of the SIL and to discuss recent demonstrations of SIL-enhanced technologies in nanophotonics.…”

Section: Introductionmentioning

confidence: 99%

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Solid immersion lens applications for nanophotonic devices

Ramsay¹

2008

J. Nanophoton

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Abstract. Solid immersion lens (SIL) microscopy combines the advantages of conventional microscopy with those of near-field techniques, and is being increasingly adopted across a diverse range of technologies and applications. A comprehensive overview of the state-of-the-art in this rapidly expanding subject is therefore increasingly relevant. Important benefits are enabled by SIL-focusing, including an improved lateral and axial spatial profiling resolution when a SIL is used in laser-scanning microscopy or excitation, and an improved collection efficiency when a SIL is used in a light-collection mode, for example in fluorescence micro-spectroscopy. These advantages arise from the increase in numerical aperture (NA) that is provided by a SIL. Other SIL-enhanced improvements, for example spherical-aberration-free sub-surface imaging, are a fundamental consequence of the aplanatic imaging condition that results from the spherical geometry of the SIL. The theory of SIL imaging exposes the unique properties of SILs that provide advantages in applications involving the interrogation of photonic and electronic nanostructures. Such applications range from the sub-surface examination of the complex three-dimensional microstructures fabricated in silicon integrated circuits, to quantum photoluminescence and transmission measurements in semiconductor quantum dot nanostructures.

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“…This asymmetry in the focal spot distribution leads to different resolutions along orthogonal directions in an image, and recently we reported the first evidence of this effect in a real image. 6 A further enhancement in resolution can be achieved by manipulating the irradiance distribution in the pupil-plane of the lens so as to reduce the dimensions of the focal spot below those obtained in the clear-pupil case. In particular, the use of annular pupil-plane apertures in the tight-focusing regime has been the subject of a number of theoretical investigations, which collectively highlighted the advantages of single and multiple-zone annular apertures for improving the lateral resolution and manipulating the focal volume and depth-of-focus through the isolation of the illuminating high spatial frequencies.…”

mentioning

confidence: 99%

70 nm resolution in subsurface optical imaging of silicon integrated-circuits using pupil-function engineering

Serrels

Ramsay

Reid

2009

Applied Physics Letters

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We present experimental evidence for the resolution-enhancing effect of an annular pupil-plane aperture when performing nonlinear imaging in the vectorial-focusing regime through manipulation of the focal spot geometry. By acquiring two-photon optical beam-induced current images of a silicon integrated-circuit using solid-immersion-lens microscopy at 1550 nm we achieved 70 nm resolution. This result demonstrates a reduction in the minimum effective focal spot diameter of 36%. In addition, the annular-aperture-induced extension of the depth-of-focus causes an observable decrease in the depth contrast of the resulting image and we explain the origins of this using a simulation of the imaging process.

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Nanoscale optical microscopy in the vectorial focusing regime

Cited by 86 publications

References 15 publications

Bessel beams: Effects of polarization

Bessel beams: Effects of polarization

Solid immersion lens applications for nanophotonic devices

70 nm resolution in subsurface optical imaging of silicon integrated-circuits using pupil-function engineering

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