Identification and Characterization of the Topside Bulge of the Venusian Ionosphere

TL;DR

This study analyzes the Venusian ionosphere's topside bulge using over 200 dayside electron density profiles from Venus Express, classifying its morphology and exploring its relation to solar activity and solar wind interaction.

Contribution

It introduces an automated classification method for the Venusian ionospheric bulge and provides insights into its morphology, occurrence, and external influences, advancing understanding of Venus's space environment.

Findings

Bulge detected in over 80% of profiles.

Type 1 bulges occur only at low latitudes.

Bulge altitude negatively correlates with SZA.

Abstract

Venus, in the absence of an intrinsic magnetic field, undergoes a direct interaction between its ionosphere and the solar wind. Previous missions, including Mariner, Venera, and the Pioneer Venus Orbiter (PVO), reported a recurring localized increase in electron density, often termed a "bulge," at altitudes between 160 and 200 km. This study investigates this topside bulge using over 200 dayside electron density profiles derived from the Venus Radio Science experiment (VeRa) onboard the Venus Express (VEX). We employ an automated, gradient-based classification algorithm to provide a quantitative and reproducible method for identifying and categorizing the bulge morphology into three types. Type 1 profiles exhibit a distinct secondary peak above the main V2 layer. Type 2 profiles display a shoulder-like feature near the bulge altitude. Type 3 bulges are not visually apparent but can be identified through residuals obtained after subtracting a Chapman layer fit to the V2 peak. The bulge is detected in over 80\% of the analyzed profiles, with a higher occurrence during periods of low solar activity and at lower solar zenith angles (SZA). Type 1 morphologies are only observed at low latitudes (within $\pm 40^\circ$). The peak altitude of the bulge negatively correlates with SZA, suggesting that thermospheric cooling toward the terminator significantly influences the bulge altitude. The occurrence patterns and morphological characteristics indicate that the bulge is likely influenced by external drivers, such as solar wind interaction, rather than being solely a result of local photochemical processes.