Abstract

We report a novel method of focus determination with high sensitivity and submicrometre accuracy. The technique relies on the asymmetry in the scattered far field from a nanosphere located at the surface of interest. The out-of-focus displacement of the probing beam manifests itself in imbalance of the signal of the differential detector located at the far field. Up–down scanning of the focussed field renders an error S-curve with a linear region that is slightly bigger than the corresponding vectorial Rayleigh range. We experimentally show that the focus can be determined not only for a surface with high optical contrast, such as a silicon wafer, but also for a weakly reflecting surface, such as fused silica glass. Further, for the probing wavelength of 405 nm, three sizes of polystyrene latex spheres, namely 200, 100, and 50 nm in diameter, are tested. Higher sensitivity was obtained as the sphere diameter became smaller. However, due to the fact that the scattering cross-section decreases as the sixth power of the nanosphere diameter, we envision that further size reduction of the studied sphere would not contribute to a drastic improvement in sensitivity. We believe that the proposed method can find applications in bio/nano detection, micromachining, and optical disk applications.

Highlights

  • Focussed light plays a vital role in modern technology in the fields of optical lithography, micro-machining, optical data storage, nanostructure characterisation, and biology [1, 2]

  • We report a novel method of focus determination with high sensitivity and submicrometre accuracy

  • The method is based on detecting the scattering in the far field of a nanoparticle that is deposited on a surface

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Summary

Introduction

Focussed light plays a vital role in modern technology in the fields of optical lithography, micro-machining, optical data storage, nanostructure characterisation, and biology [1, 2]. Non-optimal energy use of the focussed field [4], damage of the sample [5], failure to store data [6, 7], uncertainty in the localisation of cells, and lack of reproducibility of biological results [8, 9]. One can find imaging techniques dedicated to the detection of deepsubwavelength nanoparticles on top of a surface, with sizes that can be smaller than 10 nm (for example, gold nanoparticles in optical detection using interferometric schemes [10]). In addition to excellent focussing, the smoothness and flatness of the substrate

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