Diffraction of light by the gravitational field of the Sun and the solar corona

TL;DR

This paper analyzes how the Sun's gravitational field and solar corona plasma influence the propagation of light, revealing effects on amplification, resolution, and wave characteristics, especially at radio wavelengths.

Contribution

It develops a comprehensive wave-optical model combining gravity and plasma effects, extending previous results to include the solar corona's influence on the solar gravitational lens.

Findings

Solar plasma reduces light amplification and broadens the point spread function.

Plasma effects are significant at radio wavelengths, drastically affecting the SGL's performance.

At optical wavelengths, plasma effects are negligible, preserving the SGL's optical properties.

Abstract

We study the optical properties of the solar gravitational lens (SGL) under the combined influence of the static spherically symmetric gravitational field of the Sun---modeled within the first post-Newtonian approximation of the general theory of relativity---and of the solar corona---modeled as a generic, steady-state, spherically symmetric free electron plasma. For this, we consider the propagation of monochromatic electromagnetic (EM) waves near the Sun and develop a Mie theory that accounts for the refractive properties of the gravitational field of the Sun and that of the free electron plasma in the extended solar system. We establish a compact, closed-form solution to the boundary value problem, which extends previously known results into the new regime where gravity and plasma are both present. Relying on the wave-optical approach, we consider three different regions of practical importance for the SGL, including the shadow region directly behind the Sun, the region of geometrical optics and the interference region. We demonstrate that the presence of the solar plasma affects all characteristics of an incident unpolarized light, including the direction of the EM wave propagation, its amplitude and its phase. We show that the presence of the solar plasma leads to a reduction of the light amplification of the SGL and to a broadening of its point spread function. We also show that the wavelength-dependent plasma effect is important at radio frequencies, where it drastically reduces both the amplification factor of the SGL and also its angular resolution. However, for optical and shorter wavelengths, the plasma's contribution to the EM wave is negligibly small, leaving the plasma-free optical properties of the SGL practically unaffected.