© NASA/CXC/CfA/R.Kraft et al/NSF/VLA/Univ.Hertfor dshire/M.Hardcastle/ESO/VLT/ISAAC/M.Rejk uba et al.A composite Chandra image of Centaurus A showing the effects of an active supermassive black hole
Disorder is measured by a quantity called entropy, something which has been on the rise ever since the big bang. Chas Egan and Charles Lineweaver of the Australian National University in Canberra used the latest astrophysical data to calculate the total entropy of everything in the universe, from gas to gravitons.
It turns out that supermassive black holes are by far the biggest contributors to the universe's entropy. Entropy reflects the number of possible arrangements of matter and energy in an object. The number of different configurations of matter a black hole could contain is staggering because its internal state is completely mysterious.
Egan and Lineweaver found that everything within the observable universe contains about 10104 units of entropy (joules per Kelvin), a factor of 10 to 1000 times higher than previous estimates that did not include some of the biggest known black holes, submitted to The Astrophysical Journal.
If entropy were ever to reach a maximum level, that would mean the heat death of the universe. In this scenario no energy can flow, because everything is the same temperature and so life and other processes become impossible. "Our results suggest we're a little further along that road than previously thought," Egan says.
But although black holes do boost the universe's total entropy, it is not clear whether they will hasten its heat death. Supermassive black holes don't contribute much to the flows of heat that even out temperature throughout the universe, says physicist Stephen Hsu at the University of Oregon in Eugene.
It's true that these black holes will slowly evaporate by releasing Hawking radiation, particles created near the boundary of the black hole. And this radiation could move the universe towards heat death.
However, it will take some 10102 years for a supermassive black hole to evaporate. "The entropy inside those black holes is effectively locked up in there forever," Hsu says. So we may have reached a state approaching heat death long before, as stars burn out and their matter decays.
The biological life could be interpreted as the most elaborated organization of energy and matter in the physical universe. THe biggest concentration of information on earth is encoded in human beings. This order is transmitted from one generation to another. However, when a violent death occurs, this information/order disapears and the enropy makes a jump. The information?organazation in one single human being should be IMHO more important then a big ball of gaz falling into a black hole. Consequently, everytime a human being is killed, the univers jumps in time into its own doom. :D