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Heat death of the universe

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Physical cosmology
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The heat death is a possible final state of the universe, in which it has "run down" to a state of no free energy to sustain motion or life. In physical terms, it has reached maximum entropy.

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Origins of the idea

The idea of heat death stems from the second law of thermodynamics, which states that entropy tends to increase in an isolated system.

If the universe lasts for a sufficient time, it will asymptotically approach a state where all energy is evenly distributed. Hermann von Helmholtz is thought to be the first to propose the idea of heat death in 1854, 11 years before Clausius's definitive formulation of the Second law of thermodynamics in terms of entropy (1865). However, observations about the loss of available energy as heat had been formulated by Sadi Carnot as early as 1824.

Temperature of the universe

Despite the term "heat death", the temperature of the entire universe would be very close to absolute zero in this scenario. Heat death is however not quite the same as "cold death" or the "Big Freeze" in which the universe simply becomes too cold to sustain life due to continued expansion, though the result is quite similar (see: [link] for a more detailed explanation).

Current status

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Recent work in inflationary cosmology has inverted the heat death notion, suggesting that the early universe was in a thermal equilibrium and thus heat death–like state before cosmic expansion. Meanwhile, in an expanding universe, some believe the maximum possible entropy increases far more quickly than the actual entropy with each time increment, pushing the universe continually further away from an equilibrium state despite increasing entropy. Furthermore, the very notion of thermodynamic modelling of the universe has been questioned, since the effects of such factors as gravity and quantum phenomena are very difficult to reconcile with simple thermodynamic models, rendering the utility of such models as predictive systems highly doubtful according to some.

Nonetheless, assuming that the second law of thermodynamics is an appropriate model and the Universe is a closed system, the scientific evidence overwhelmingly points to an eventual heat death.

However, see Final anthropic principle for a discussion of the idea that the second law does not imply life's eventual extinction.

Timeline for Heat Death

This is an asteroid, one of the last survivors in a dying Universe. In reality it's unlikely the object would be illuminated by a surviving star and would probably be immersed in darkness during this Age.
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This is an asteroid, one of the last survivors in a dying Universe. In reality it's unlikely the object would be illuminated by a surviving star and would probably be immersed in darkness during this Age.

The Degenerate Age - from 1014 to 1040 years

Galaxy and Star Formation Ceases: 1014 years

Stellar formation stops, leaving matter to decay over a very long period of time. The hydrogen fuel used for fusion by stars will be eventually depleted, leaving all matter in the Universe in a compact state populated by the following objects after all stars burn out: Formerly luminous bodies like stars cool and dim, eventually reaching the same temperature as the Universe's microwave background radiation.

Planets are Flung from Orbits: 1015 years

Over time, the orbits of planets are kicked into other masses (see above) or scattered throughout the Universe due to gravitational perturbations.

Stars are Flung from Orbits: 1016 years

The same scattering effect happens to stars and their remnants within galaxies, leaving mostly scattered stellar debris and supermassive black holes
The mighty supermassive black holes are all that remains of galaxies once all protons decay, but even these giants are not immortal.
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The mighty supermassive black holes are all that remains of galaxies once all protons decay, but even these giants are not immortal.

An estimated 1/2 of Protons Decay: 1036 years

If estimates on the half-life of protons are correct, then one-half of all the free-floating matter in the Universe has been converted into gamma radiation through proton decay

All Protons Decay: 1040 years

If estimates on the half-life of protons are correct, then these particles (and nucleonic neutrons as well) have now undergone roughly 10,000 half-lives. To put this into perspective: There are an estimated 1080 protons in the Universe, and the estimated half-life for protons is 1036 years. That means the proton's numbers have been slashed in half 10,000 times. If one does the math, there are now roughly 10-3,000 as many protons as there were at the beginning of the Universe. So that means the total number of remaining protons in the Universe at the end of the Degenerate Age would be far less than one (a very tiny fraction something like 3,000 zeroes after the decimal place before the first significant digit). Effectively, all matter is now contained in the only bodies in the Universe immune to proton decay: black holes

Note: This number is based on loose estimates as the exact value for the half-life of protons is an unknown quantity with only a known lower-bound. The end of the Degenerate Era is meant to mark the end of baryonic matter's influence on the Universe, so the estimate for how long this era will last may change if and when the exact value for proton decay is pinned down. The specific numerical values are not meant to be taken literally, and are provided only for demonstration purposes.

The Black Hole Age - from 1040 years to 10100 years

Black Holes Dominate: 1040 years

Black holes continue to evaporate via Hawking radiation, but this process is very slow. The first to go are the small ones, then the medium sized ones, and eventually the supermassive black holes too eventually decay into photons.

Black Holes Disintegrate: 10100 years

Few if any black holes remain; virtually all matter is now converted into photons.

See also 1019 seconds for times further than 3 billion years into the future.

Ultimate fate

The lowly photon is now king of the Universe as the last of the supermassive black holes evaporate.
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The lowly photon is now king of the Universe as the last of the supermassive black holes evaporate.

The Dark Age - from 10100 years until 10150 years

All Black Holes now Disintegrated: 10150 years

The remaining black holes evaporate: first the small ones, and then the supermassive black holes. All matter that used to make up the stars and galaxies has now degenerated into photons

The Photon Age - from 10150 years until the Distant Future

The Universe Achieves Low-Energy State: 101000 years and beyond

The Universe now reaches extreme low-energy state. What happens after this is speculative. It's possible a Big Rip event may occur far off into the future, or the Universe may settle into this state forever, achieving true heat death. Extreme low-energy states imply that localized quantum events become major macro-scale phenomenon rather than micro-scale non-events because the smallest pertubations make the biggest difference in this era, so there is no telling what may happen to space or time during this era.

See also

External links

 

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