Abstract
This paper describes a novel optical system that can be integrated to the image port of an existing brightfield microscope in order to enhance the microscope with the features of digital holographic microscopy. The proposed system is modular and portable. It is relatively inexpensive and robust to vibrations due to its compact design. An additional benefit is that the system does not need to undergo path-length realignment if the sample is changed, unlike several other architectures. The module is based on a square in-line Mach–Zender architecture but achieves the off-axis condition using two sets of wedge prism pairs. This design offers a significant advantage over competing Mach–Zender nearly common-path modules in terms of path length matching of object and reference wavefields for the case of low-temporal coherence sources, which are preferable for low noise phase imaging. An additional advantage that the proposed system has when compared with similar modules is the facility to continuously vary the tilt angles of the object and reference wavefields that are incident on the sensor, which enables the module to be readily adapted to any given microscope and camera. We provide a detailed overview of the module design and construction. Experimental results are demonstrated on a micro-lens array as well as buccal epithelial cells. We also provide a detailed discussion on the relationship between the proposed self-reference module and related common-path and nearly common-path holographic modules that have previously been proposed in the literature.
Highlights
Quantitative phase imaging (QPI) [1,2] refers to a set of emerging optical techniques that enable real-time measurement of the phase-delay introduced by a specimen, and provides a powerful means to study cellular dynamics relating to nanometric changes in cell morphology [3,4]
Other applications include imaging semiconductors [5] and the study of material composition [6]. This set of methods includes coherent interferometry known as digital holographic microscopy (DHM), refs. [3,4,7,8] as well as partially coherent white-light methods such as spatial light interference microscopy (SLIM) [9,10], differential phase contrast (DPC) [11,12], transport-of-intensity equation (TIE) [13,14], lensless microscopy [15,16]
Like the ‘partial coherence tau-interferometer’ the system is portable and can be added to the output port of an existing microscope, it is inexpensive and has a small form factor; it is robust to vibration and to differential noise as well as not requiring realignment of the reference when different samples are imaged
Summary
Quantitative phase imaging (QPI) [1,2] refers to a set of emerging optical techniques that enable real-time measurement of the phase-delay introduced by a specimen, and provides a powerful means to study cellular dynamics relating to nanometric changes in cell morphology [3,4]. Other applications include imaging semiconductors [5] and the study of material composition [6] This set of methods includes coherent interferometry known as digital holographic microscopy (DHM), refs. [3,4,7,8] as well as partially coherent white-light methods such as spatial light interference microscopy (SLIM) [9,10], differential phase contrast (DPC) [11,12], transport-of-intensity equation (TIE) [13,14], lensless microscopy [15,16] All of these methods provide an estimate of the quantitative phasedelay introduced by the sample but they vary in terms of ease of implementation, accuracy, depth of field, and coherent noise.
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