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stockholmuniversity.zoom.us/j/940229961
Magnetic fields are a dynamically important component of the turbulent interstellar medium (ISM) of star-forming galaxies. These magnetic fields are due to a dynamo action, which is a process of converting turbulent kinetic energy to magnetic energy. A dynamo that acts at scales less than the turbulent driving scale is known as the turbulent dynamo. The ISM is a multiphase medium and observations suggests that the properties of magnetic fields differ with the phase. Here, we aim to study how the properties of the turbulent dynamo depend on the phase. We simulate the non-isothermal turbulent dynamo in a two-phase medium (most previous work assumes an isothermal gas). We find that the growth rate of magnetic fields in the exponentially growing stage is similar in both the phases, and this is because of a roughly equal amount of vorticity being generated in each phase. We further compute each term responsible for amplification and destruction of vorticity and show that the amplification of vorticity by turbulent motions is a dominant term (similar in both the phases) followed by the baroclinic term (only present in non-isothermal gases, higher in the warm phase) and the term for viscous interactions in the presence of logarithmic density gradients (higher in the cold phase). We find that the final ratio of magnetic to turbulent kinetic energy is lower due to a stronger Lorentz force. We find that the non-isothermal turbulent dynamo is less efficient than its isothermal counterpart.
https://ui.adsabs.harvard.edu/abs/2022arXiv220208324S/abstract