Modelling the influence of meteoric smoke particles on artificial heating in the D-region

Margaretha Myrvang,Ingrid Mann,Carsten Baumann

doi:10.5194/angeo-39-1055-2021

Margaretha Myrvang, Ingrid Mann + Show 1 more

Open Access

https://doi.org/10.5194/angeo-39-1055-2021

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Abstract

Abstract. We investigate if the presence of meteoric smoke particles (MSPs) influences the electron temperature during artificial heating in the D-region. By transferring the energy of powerful high-frequency radio waves into thermal energy of electrons, artificial heating increases the electron temperature. Artificial heating depends on the height variation of electron density. The presence of MSPs can influence the electron density through charging of MSPs by electrons, which can reduce the number of free electrons and even result in height regions with strongly reduced electron density, so-called electron bite-outs. We simulate the influence of the artificial heating by calculating the intensity of the upward-propagating radio wave. The electron temperature at each height is derived from the balance of radio wave absorption and cooling through elastic and inelastic collisions with neutral species. The influence of MSPs is investigated by including results from a one-dimensional height-dependent ionospheric model that includes electrons, positively and negatively charged ions, neutral MSPs, singly positively and singly negatively charged MSPs, and photochemistry such as photoionization and photodetachment. We apply typical ionospheric conditions and find that MSPs can influence both the magnitude and the height profile of the heated electron temperature above 80 km; however, this depends on ionospheric conditions. During night, the presence of MSPs leads to more efficient heating and thus a higher electron temperature above altitudes of 80 km. We found differences of up to 1000 K in electron temperature for calculations with and without MSPs. When MSPs are present, the heated electron temperature decreases more slowly. The presence of MSPs does not much affect the heating below 80 km for night conditions. For day conditions, the difference between the heated electron temperature with MSPs and without MSPs is less than 25 K. We also investigate model runs using MSP number density profiles for autumn, summer and winter. The night-time electron temperature is expected to be 280 K hotter in autumn than during winter conditions, while the sunlit D-region is 8 K cooler for autumn MSP conditions than for the summer case, depending on altitude. Finally, an investigation of the electron attachment efficiency to MSPs shows a significant impact on the amount of chargeable dust and consequently on the electron temperature.

Highlights

Meteoric smoke particles (MSPs) are small nanometer-sized dust particles (Hunten et al, 1980; Plane, 2012)
We apply typical ionospheric conditions and find that MSPs can influence both the magnitude and the height profile of the heated electron temperature above 80 km; this depends on ionospheric conditions
The ionospheric D-region varies in altitude range from about 50 to 100 km; we model up to 120 km to see if the electron temperature at altitudes above 100 km is influenced by the presence of MSPs at lower altitudes below

Summary

Introduction

Meteoric smoke particles (MSPs) are small nanometer-sized dust particles (Hunten et al, 1980; Plane, 2012) They can change the D-region charge balance by influencing the chemical processes through charging of MSPs by electrons and ions (see Baumann et al, 2015). Megner et al (2006) calculates the MSP number density profile by using a one-dimensional model, where the MSP height distribution varies with size. For the charging of a MSP by electrons, the electron attachment efficiency is the probability of a MSP capturing an electron Baumann et al (2013) apply the electron attachment efficiency (γcharging) from Megner and Gumbel (2009) to the ionospheric model.

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