Thermodynamic Behavior of Friedmann Equation at Apparent Horizon of FRW Universe

Abstract

It is shown that the differential form of Friedmann equation of a FRW universe can be rewritten as a universal form dE = TdS + WdV at apparent horizon, where E and V are the matter energy and volume inside the apparent horizon (the energy E is the same as the Misner-Sharp energy in the case of Einstein general relativity), W=(-P)/2 is the work density and and P are energy density and pressure of the matter in the universe, respectively. From the thermodynamic identity one can derive that the apparent horizon has associated entropy S= A/4G and temperature T = / 2π in Einstein general relativity, where A is the area of apparent horizon and is the surface gravity at apparent horizon. We extend our procedure to the Gauss-Bonnet gravity and more general Lovelock gravity and show that the differential form of Friedmann equations in these gravities can also be rewritten to thee universal form dE = TdS + WdV at the apparent horizon with entropy S being given by expression previously known via black hole thermodynamics.

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