Magnetic field formation in the Milky Way like disc galaxies of the Auriga project

The magnetic fields observed in the Milky Way and nearby galaxies appear to be in equipartition with the turbulent, thermal and cosmic ray energy densities, and hence are expected to be dynamically important. However, the origin of these strong magnetic fields is still unclear, and most previous attempts to simulate galaxy formation from cosmological initial conditions have ignored them altogether. Here, we analyse the magnetic fields predicted by the simulations of the Auriga Project, a set of 30 high-resolution cosmological zoom simulations of Milky Way like galaxies, carried out with a moving-mesh magnetohydrodynamics code and a detailed galaxy formation physics model. We find that the magnetic fields grow exponentially at early times owing to a small-scale dynamo with an e-folding time of roughly 100 Myr in the centre of haloes until saturation occurs around z = 2–3, when the magnetic energy density reaches about 10 per cent of the turbulent energy density with a typical strength of 10--50μG 10--50μG . In the galactic centres, the ratio between magnetic and turbulent energies remains nearly constant until z = 0. At larger radii, differential rotation in the discs leads to linear amplification that typically saturates around z = 0.5–0. The final radial and vertical variations of the magnetic field strength can be well described by two joint exponential profiles, and are in good agreement with observational constraints. Overall, the magnetic fields have only little effect on the global evolution of the galaxies as it takes too long to reach equipartition. We also demonstrate that our results are well converged with numerical resolution.

[1]  Donald P. Cox,et al.  Galactic hydrostatic equilibrium with magnetic tension and cosmic-ray diffusion , 1990 .

[2]  R. Beck,et al.  Magnetic fields in spiral galaxies , 1990, 1509.04522.

[3]  D. Sokoloff,et al.  Galactic Magnetism: Recent developments and perspectives , 1996 .

[4]  R. Kulsrud,et al.  the Origin of Cosmic Magnetic Fields , 1996 .

[5]  P. Roe,et al.  A Solution-Adaptive Upwind Scheme for Ideal Magnetohydrodynamics , 1999 .

[6]  V. Springel,et al.  Cosmological smoothed particle hydrodynamics simulations: a hybrid multiphase model for star formation , 2002, astro-ph/0206393.

[7]  T. D. Matteo,et al.  Modelling feedback from stars and black holes in galaxy mergers , 2004, astro-ph/0411108.

[8]  Imperial College London,et al.  Simulations of the Small-Scale Turbulent Dynamo , 2003, astro-ph/0312046.

[9]  K. Kusano,et al.  A multi-state HLL approximate Riemann solver for ideal magnetohydrodynamics , 2005 .

[10]  Masamune Oguri,et al.  Biermann Mechanism in Primordial Supernova Remnant and Seed Magnetic Fields , 2005 .

[11]  D. Sokoloff,et al.  Galactic dynamo and helicity losses through fountain flow , 2005, astro-ph/0512592.

[12]  S. Owley,et al.  Simulations of the Small-scale Turbulent Dynamo , 2008 .

[13]  Simon J. Lilly,et al.  Strong magnetic fields in normal galaxies at high redshift , 2008, Nature.

[14]  R. Teyssier,et al.  Cosmological MHD simulation of a cooling flow cluster , 2008, 0802.0490.

[15]  E. Vishniac,et al.  GROWTH OF MAGNETIC FIELDS INDUCED BY TURBULENT MOTIONS , 2008, 0812.0817.

[16]  M. Hanasz,et al.  GLOBAL GALACTIC DYNAMO DRIVEN BY COSMIC RAYS AND EXPLODING MAGNETIZED STARS , 2009, 0907.4891.

[17]  Peng Wang,et al.  MAGNETOHYDRODYNAMIC SIMULATIONS OF DISK GALAXY FORMATION: THE MAGNETIZATION OF THE COLD AND WARM MEDIUM , 2007, 0712.0872.

[18]  K. Dolag,et al.  Cluster magnetic fields from galactic outflows , 2008, 0808.0919.

[19]  R. Teyssier,et al.  Magnetised winds in dwarf galaxies , 2009, 0908.3862.

[20]  T. Landecker,et al.  The Dynamic Interstellar Medium: A Celebration of the Canadian Galactic Plane Survey , 2010 .

[21]  A. Fletcher Magnetic fields in nearby galaxies , 2010, 1104.2427.

[22]  V. Springel E pur si muove: Galilean-invariant cosmological hydrodynamical simulations on a moving mesh , 2009, 0901.4107.

[23]  J. Ott,et al.  A lower limit of 50 microgauss for the magnetic field near the Galactic Centre , 2010, Nature.

[24]  Andreas Bauer,et al.  Magnetohydrodynamics on an unstructured moving grid , 2011, 1108.1792.

[25]  Klaus Dolag,et al.  Origin of strong magnetic fields in Milky Way-like galactic haloes , 2012, 1202.3349.

[26]  Magnetic fields during high redshift structure formation , 2012, 1211.4356.

[27]  R. Durrer,et al.  Cosmological magnetic fields: their generation, evolution and observation , 2013 .

[28]  V. Springel,et al.  A model for cosmological simulations of galaxy formation physics: multi-epoch validation , 2013, 1305.4931.

[29]  V. Springel,et al.  Simulations of magnetic fields in isolated disc galaxies , 2012, 1212.1452.

[30]  R. Klessen,et al.  Magnetic Field Amplification in Young Galaxies , 2013, 1310.0853.

[31]  A. Basu,et al.  Magnetic fields in nearby normal galaxies: energy equipartition , 2013, 1305.2746.

[32]  C. Gheller,et al.  On the amplification of magnetic fields in cosmic filaments and galaxy clusters , 2014, 1409.2640.

[33]  V. Springel,et al.  MAGNETIC FIELDS IN COSMOLOGICAL SIMULATIONS OF DISK GALAXIES , 2013, 1312.2620.

[34]  V. Springel,et al.  The formation of disc galaxies in high-resolution moving-mesh cosmological simulations , 2013, 1305.5360.

[35]  Cfa,et al.  The large-scale properties of simulated cosmological magnetic fields , 2015, 1506.00005.

[36]  S. White,et al.  The EAGLE project: Simulating the evolution and assembly of galaxies and their environments , 2014, 1407.7040.

[37]  E. Ostriker,et al.  VERTICAL EQUILIBRIUM, ENERGETICS, AND STAR FORMATION RATES IN MAGNETIZED GALACTIC DISKS REGULATED BY MOMENTUM FEEDBACK FROM SUPERNOVAE , 2015, 1511.00010.

[38]  G. Kauffmann,et al.  On the stellar halo metallicity profile of Milky Way-like galaxies in the Auriga simulations. , 2015, 1512.03064.

[39]  V. Springel,et al.  Vertical disc heating in Milky Way-sized galaxies in a cosmological context , 2015, 1512.02219.

[40]  M. Vogelsberger,et al.  Effects of simulated cosmological magnetic fields on the galaxy population , 2015, 1508.06631.

[41]  V. Springel,et al.  GALACTIC WINDS DRIVEN BY ISOTROPIC AND ANISOTROPIC COSMIC-RAY DIFFUSION IN DISK GALAXIES , 2016, 1605.00643.

[42]  C. Federrath Magnetic field amplification in turbulent astrophysical plasmas , 2016, Journal of Plasma Physics.

[43]  S. White,et al.  A fully cosmological model of a Monoceros-like ring , 2015, 1509.08459.

[44]  R. Teyssier,et al.  A small-scale dynamo in feedback-dominated galaxies as the origin of cosmic magnetic fields – I. The kinematic phase , 2015, Monthly Notices of the Royal Astronomical Society.

[45]  M. Krumholz,et al.  Is turbulence in the interstellar medium driven by feedback or gravity? An observational test , 2015, 1512.03439.

[46]  S. White,et al.  Properties of H i discs in the Auriga cosmological simulations , 2016, 1610.01594.

[47]  R. Beck,et al.  Radio polarization and magnetic field structure in M 101 , 2016, 1601.06171.

[48]  Volker Springel,et al.  Improving the convergence properties of the moving-mesh code AREPO , 2015, 1503.00562.

[49]  S. White,et al.  Warps and waves in the stellar discs of the Auriga cosmological simulations , 2016, 1606.06295.

[50]  Federico Marinacci,et al.  The Auriga Project: the properties and formation mechanisms of disc galaxies across cosmic time , 2016, 1610.01159.