Tuesday, 26 July 2016

thermodynamics - Black hole entropy versus entropy of normal matter



It has been established that the entropy of a black hole is equal to:


$$ \frac{1}{4} \frac{c^3 A}{ G \hbar} k$$


Which if one substitutes for A the surface area of the event horizon:


$$16\pi\frac{G^2M^2}{c^4}$$


One gets for the entropy:


$$8\pi^2\frac{GM^2}{hc}k$$


My question is the following:


Entropy for ordinary matter very roughly scales with the number of particles in the system. Which for stars mostly composed of fully ionized hydrogen is proportional to the mass of the system. However for black holes this seems to scale with the mass squared.





  • Why is this?




  • Does this seem to imply that matter falling into a black hole is heated to such an extreme that more particles are created (from energy gained by gravity or by decomposition of nuclei and nucleons into constituent particles) in such high numbers that entropy seems to have this proportionality to the mass squared?




  • Do neutron stars have a similar relationship?







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