A New Measurement of the Temperature Density Relation of the IGM From Voigt Profile Fitting

Abstract

We decompose the Lyman-α (Lyα) forest of an extensive sample of 74 high signal-to-noise ratio and high-resolution quasar spectra into a collection of Voigt profiles. Absorbers located near caustics in the peculiar velocity field have the smallest Doppler parameters, resulting in a low-b cutoff in the b-NHI set by the thermal state of intergalactic medium (IGM). We fit this cutoff as a function of redshift over the range 2.0≤ z ≤ 3.4, which allows us to measure the evolution of the IGM temperature-density (T= T0 (/ 0)γ-1) relation parameters T0 and γ. We calibrate our measurements against Lyα forest simulations, using 21 different thermal models of the IGM at each redshift, also allowing for different values of the IGM pressure smoothing scale. We adopt a forward-modeling approach and self-consistently apply the same algorithms to both data and simulations, propagating both statistical and modeling uncertainties via Monte Carlo. The redshift evolution of T0 shows a suggestive peak at z=2.8, while our evolution of γ is consistent with γ 1.4 and disfavors inverted temperature-density relations. Our measured evolution of T0 and γ are generally in good agreement with previous determinations in the literature. Both the peak in the evolution of T0 at z = 2.8, as well as the high temperatures T0 15000-20000\,K that we observe at 2.4 < z < 3.4, strongly suggest that a significant episode of heating occurred after the end of HI reionization, which was most likely the cosmic reionization of HeII.