Comparative analysis of imaging configurations and objectives for Fourier microscopy

TL;DR

This paper provides a comprehensive analysis of optical microscope objectives and configurations for Fourier microscopy, highlighting aberrations and optimal setups to improve quantitative Fourier space measurements of nanostructures and emitters.

Contribution

It introduces a detailed framework for evaluating microscope objectives in Fourier microscopy, including modeling, aberration analysis, and recommendations for optimal configurations.

Findings

Identified optimal objective class for Fourier microscopy.

Analyzed aberrations affecting Fourier space measurements.

Provided publicly available Zemax files for reproducibility.

Abstract

Fourier microscopy is becoming an increasingly important tool for the analysis of optical nanostructures and quantum emitters. However, achieving quantitative Fourier space measurements requires a thorough understanding of the impact of aberrations introduced by optical microscopes, which have been optimized for conventional real-space imaging. Here, we present a detailed framework for analyzing the performance of microscope objectives for several common Fourier imaging configurations. To this end, we model objectives from Nikon, Olympus, and Zeiss using parameters that were inferred from patent literature and confirmed, where possible, by physical disassembly. We then examine the aberrations most relevant to Fourier microscopy, including the alignment tolerances of apodization factors for different objective classes, the effect of magnification on the modulation transfer function, and vignetting-induced reductions of the effective numerical aperture for wide-field measurements. Based on this analysis, we identify an optimal objective class and imaging configuration for Fourier microscopy. In addition, as a resource for future studies, the Zemax files for the objectives and setups used in this analysis have been made publicly available.