Informations générales
Intitulé de l'offre : M/F - DOCTORAL STUDENT - Fine structure of type III solar radio bursts (H/F)
Référence : UMR7328-ISALAN-041
Nombre de Postes : 1
Lieu de travail : ORLEANS
Date de publication : mardi 4 mars 2025
Type de contrat : CDD Doctorant
Durée du contrat : 36 mois
Date de début de la thèse : 1 octobre 2025
Quotité de travail : Complet
Rémunération : 2200 gross monthly
Section(s) CN : 17 - Système solaire et univers lointain
Description du sujet de thèse
Fine structure of type III solar radio bursts
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The Parker Solar Probe (PSP) mission, launched in 2018, has given us an unprecedented view of the inner heliosphere, revealing a solar atmosphere that is much more structured than expected. Starting in 2024, the spacecraft will fly as close as 9.8 solar radii from the Sun, making it the first to literally penetrate a stellar atmosphere.
Among the phenomena that are currently receiving a great deal of attention are the so-called Type III solar radio bursts. These are generated by a multistage process in which an energetic electron beam emitted by the Sun is expected to generate Langmuir waves, which are then converted into electromagnetic waves by nonlinear processes in which electron density fluctuations play an important role.
What makes PSP truly unique compared to all other missions is its ability to directly observe this nonlinear conversion process in situ, before the beam has begun to relax. Interestingly, PSP is equipped with two sets of instruments that provide high-quality observations of these Type III radio bursts and their local signature: electric field antennas and the SCM search-coil magnetometer built and used by LPC2E. The latter has a high-frequency sensor covering the frequency range of the waves of interest (0.01-2 MHz).
In a recent series of articles, members of our team have provided the first unambiguous evidence for the existence of a slow electromagnetic mode and of harmonics that are essential for a full understanding of the interaction processes.
These studies have benefited greatly from observations made with the SCM search coil. Indeed, these observations allow the mode of the primary waves to be determined, and in addition allow electrostatic and electromagnetic waves to be separated when observed in situ. The bursty nature of the generation mechanisms leads to an energy dissipation and a modification of the particle distribution function that is very different from what conventional quasilinear theory of beam-plasma interactions provides.
The main objective of this work is precisely to study this relaxation process. This will be done by a detailed analysis of the polarisation properties of Type III radio bursts. The analysis will be based mainly on PSP observations (due to its proximity to the Sun). However, observations from the Solar Orbiter mission, which carries the same set of instruments (including an SCM magnetometer from LPC2E), will also be considered, as there are only a few events so far where an electron beam happens to pass close to the spacecraft.
Contexte de travail
The doctoral candidate will be integrated into the Space team of the Laboratoire de Physique et Chimie de l'Environnement et de l'Espace (LPC2E, https://www.lpc2e.cnrs.fr/) based in Orléans. This multidisciplinary team is heavily involved in various space missions such as Rosetta, Solar Orbiter and Parker Solar Probe.
The three supervisors of this thesis have complementary expertise: Säm Krucker (SSL Berkeley, and Univ. of Applied Sciences Northwestern Switzerland) will bring his expertise in the measurement and analysis of energetic particle distributions from both missions; Vladimir Krasnoselskikh (LPC2E, Orléans) will bring his expertise in the theoretical modelling of beam-plasma interactions, and Thierry Dudok de Wit (LPC2E, Orléans, and ISSI, Bern) will bring his expertise in the data analysis. All are deeply involved in the Solar Orbiter and Parker Solar Probe missions.
The aim of the thesis is to provide the PhD student with comprehensive training, including practical aspects such as data extraction and pre-processing, the development of multi-instrument analysis skills, and a solid understanding of the physical processes that play a key role in heliospheric and astrophysical plasmas. The work will be essentially exploratory, and will therefore require a high degree of autonomy. A solid grounding in space physics is required, as well as a high degree of fluency in data analysis.
Contraintes et risques
Applications must mandatorily be done by 14 mars 2025 via the CNES website: https://recrutement.cnes.fr/fr/annonce/3428731-25-288-fine-structure-of-type-iii-solar-radio-bursts-45100-orleans
Informations complémentaires
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