X-Ray Scaling Relations of Galaxy Groups in a Hydrodynamic Cosmological Simulation
Abstract
We examine the scalings of X-ray luminosity, temperature, and dark matter or galaxy velocity dispersion for galaxy groups in an LCDM cosmological simulation, which incorporates gravity, gas dynamics, radiative cooling, and star formation, but no substantial non-gravitational heating. In agreement with observations, the simulated LX-sigma and LX-TX relations are steeper than those predicted by adiabatic simulations or self-similar models, with LX sigma4.4 and LX TX2.6 for massive groups and significantly steeper relations below a break at sigma~180 km/s (TX~0.7 keV), but TX-sigma is fairly close to self-similar, with TX sigma1.75. The entropy of hot gas in low mass groups is higher than predicted by self-similar scaling, and agrees with observations that suggest an "entropy floor". The steeper scalings of the luminosity relations are driven by radiative cooling, which reduces the hot gas fraction from 50% of the total baryons at sigma ≈ 500 km/s to 20% at sigma ≈ 100 km/s. A secondary effect is that hot gas in smaller systems is less clumpy, further driving down LX. A smaller volume simulation with eight times higher mass resolution predicts nearly identical X-ray luminosities at a given group mass, demonstrating the insensitivity of the predicted scaling relations to numerical resolution. There remain some quantitative discrepancies: the predicted mass scale of the LX-TX and LX-sigma breaks is somewhat too low, and the luminosity-weighted temperatures are too high at a given sigma. We conclude that radiative cooling has an important quantitative impact on group X-ray properties and can account for many of the observed trends that have been interpreted as evidence for non-gravitational heating. (abridged)
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