Effects of Solar Activity, Solar Insolation and the Lower Atmospheric Dust on the Martian Thermosphere

TL;DR

This study analyzes how solar activity, insolation, and atmospheric dust influence the Martian thermosphere, quantifying their effects on temperature and density variations using regression analysis and historical data.

Contribution

It introduces a multiple linear regression methodology to quantify the impacts of solar and dust forcings on the Martian thermosphere, including historical extrapolation.

Findings

A 100 sfu increase in solar flux raises temperature by approx. 136 K.

Dust storms significantly increase thermospheric temperatures and densities.

Dust effects are more pronounced during solar minimum periods.

Abstract

A diagnosis of the Ar densities measured by the Neutral Gas and Ion Mass Spectrometer aboard the Mars Atmosphere and Volatile EvolutioN (MAVEN) and the temperatures derived from these densities shows that solar activity, solar insolation, and the lower atmospheric dust are the dominant forcings of the Martian thermosphere. A methodology, based on multiple linear regression analysis, is developed to quantify the contributions of the dominant forcings to the densities and temperatures. The results of the present study show that a 100 sfu (solar flux units) change in the solar activity results in approx. 136 K corresponding change in the thermospheric temperatures. The solar insolation constrains the seasonal, latitudinal, and diurnal variations to be interdependent. Diurnal variation dominates the solar insolation variability, followed by the latitudinal and seasonal variations. Both the global and regional dust storms lead to considerable enhancements in the densities and temperatures of the Martian thermosphere. Using past data of the solar fluxes and the dust optical depths, the state of the Martian thermosphere is extrapolated back to Martian year (MY) 24. While the global dust storms of MY 25, MY 28 and MY 34 raise the thermospheric temperatures by approx. 22-38 K, the regional dust storm of MY 34 leads to approx. 15 K warming. Dust driven thermospheric temperatures alone can enhance the hydrogen escape fluxes by 1.67-2.14 times compared to those without the dust. Dusts effects are relatively significant for global dust storms that occur in solar minimum compared to those that occur in solar maximum.