Estimation of the CMB temperature from atomic C\, i and molecular CO lines in the interstellar medium of early galaxies

Abstract

The linear increase of the cosmic microwave background (CMB) temperature with cosmological redshift, T CMB = T0(1 + z), is a prediction of the standard cosmological model. There are currently two methods to measure this dependence at redshift z>0, and that is equally important to estimate the CMB temperature T0 at the present epoch z=0. The first method is based on the Sunyaev-Zeldovich (SZ) effect for a galaxy cluster. aThe second method is based on the analysis of the populations of atomic and molecular energy levels observed in the absorption spectra of quasars. This method allows T CMB(z) to be measured directly. We present new estimates of T CMB(zi) in the redshift range 1.7 zi 3.3 based on the analysis of excitation of the CO rotational levels and C\, i fine-structure levels in 15 absorption systems. We take into account collisional excitation of CO and C\, i with hydrogen atoms and H2 and radiative pumping of C\, i by the interstellar ultraviolet radiation. Applying this corrections leads to a systematic decrease in the previously obtained estimates of T CMB(zi) (for some systems the magnitude of the effect is 10\%). Combining our measurements with the measurements of T CMB(z) in galaxy clusters we have obtained a constraint on the parameter β=+0.0100.013, which characterizes the deviation of the CMB temperature from the standard relation, T CMB = T0(1 + z)1-β, and an independent estimate of the CMB temperature at the present epoch, T0 = 2.7190.009\,K, which agrees well with the estimate from orbital measurements, T0 = 2.72550.0006\,K. This independent estimate is very important because it was obtained using cosmological data, in contrast to satellite measurements, which are obtained "here" and "now".