Zernike mode rescaling extends capabilities of adaptive optics for microscopy

TL;DR

This paper investigates how Zernike mode rescaling can extend adaptive optics capabilities in microscopy by enabling efficient correction of higher-order aberrations with low-order modes, despite the loss of orthogonality in Gaussian beams.

Contribution

It reveals the influence of aberration radius on Zernike mode cross-coupling and proposes leveraging this effect for simplified aberration correction in adaptive optics.

Findings

Aberration radius affects Zernike mode cross-coupling.

Low-order Zernike modes can compensate higher-order aberrations.

Potential for simpler adaptive optics devices in microscopy.

Abstract

Zernike polynomials are widely used mathematical models of experimentally observed optical aberrations. Their useful mathematical properties, in particular their orthogonality, make them a ubiquitous basis set for solving various problems in beam optics. Thus they have found widespread use in adaptive optics realizations that are used to correct wavefront aberrations. However, Zernike aberrations lose their orthogonality when used in combination with Gaussian beams, which are omnipresent in real-world optical applications. As a consequence, Zernike aberrations in Gaussian beams start to cross-couple between each other, a phenomenon that does not occur for Zernike aberrations in plane waves. Here, we describe how the aberration radius influences this cross-coupling of Zernike aberrations. Furthermore, we propose that this effect can actually be harnessed to allow efficient compensation of higher-order aberrations using only low-order Zernike modes. This finding has important practical implications, as it suggests the possibility of using adaptive optics devices with low element numbers to compensate aberrations which would normally require more complex and expensive devices.