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| Funder | Swedish Research Council |
|---|---|
| Recipient Organization | Swedish Institute of Space Physics |
| Country | Sweden |
| Start Date | Jan 01, 2024 |
| End Date | Dec 31, 2026 |
| Duration | 1,095 days |
| Number of Grantees | 1 |
| Roles | Principal Investigator |
| Data Source | Swedish Research Council |
| Grant ID | 2023-05048_VR |
Most of the visible Universe is in a highly ionized plasma state.
Plasma processes are operating work everywhere, from radio galaxy jets and supernova explosions to solar flares and planetary magnetospheres.
The Sun is our nearest star and the most important to our life, but it is the only star we have a chance of understanding how it works in detail and how it interacts with the surrounding environment.
The outer part of the Sun´s atmosphere, called the corona, is formed of plasma which is much hotter than the layers underneath it.
It also constantly expands, forming a flow of plasma with embedded magnetic fields called the solar wind, which fills all the space around the Sun.
This wind creates a plasma bubble that extends for over 100 astronomical units and has all the planets of the solar system within it.
The processes responsible for heating the plasma of the corona and accelerating the solar wind are a subject of active debate.The project concerns circularly polarized waves near the proton cyclotron frequency.
Due to their frequency, such waves can effectively interact with solar wind protons, potentially playing an important role in solar wind heating.
Despite numerous observations of such waves, it is still unclear to which plasma wave mode they correspond and, therefore, how they interact with the plasma ions.
Here, we study the waves at varying heliospheric distances and understand their role in the heating of the solar wind Solar Orbiter using data and simulations.
Swedish Institute of Space Physics
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