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Future of an expanding universe

January 01, 1970

Current observations suggest that the expansion of the universe will continue forever. The prevailing theory is that the universe will cool as it expands, eventually becoming too cold to sustain life. For this reason, this future scenario once popularly called "Heat Death" is now known as the "Big Chill" or "Big Freeze".[1][2]

If dark energy—represented by the cosmological constant, a constant energy density filling space homogeneously,[3] or scalar fields, such as quintessence or moduli, dynamic quantities whose energy density can vary in time and space—accelerates the expansion of the universe, then the space between clusters of galaxies will grow at an increasing rate. Redshift will stretch ancient, incoming photons (even gamma rays) to undetectably long wavelengths and low energies.[4] Stars are expected to form normally for 1012 to 1014 (1–100 trillion) years, but eventually the supply of gas needed for star formation will be exhausted. As existing stars run out of fuel and cease to shine, the universe will slowly and inexorably grow darker.[5][6] According to theories that predict proton decay, the stellar remnants left behind will disappear, leaving behind only black holes, which themselves eventually disappear as they emit Hawking radiation.[7] Ultimately, if the universe reaches thermodynamic equilibrium, a state in which the temperature approaches a uniform value, no further work will be possible, resulting in a final heat death of the universe.[8]

Cosmology edit

Infinite expansion does not determine the overall spatial curvature of the universe. It can be open (with negative spatial curvature), flat, or closed (positive spatial curvature), although if it is closed, sufficient dark energy must be present to counteract the gravitational forces or else the universe will end in a Big Crunch.[9]

Observations of the Cosmic microwave background by the Wilkinson Microwave Anisotropy Probe and the Planck mission suggest that the universe is spatially flat and has a significant amount of dark energy.[10][11] In this case, the universe might continue to expand at an accelerating rate. The acceleration of the universe's expansion has also been confirmed by observations of distant supernovae.[9] If, as in the concordance model of physical cosmology (Lambda-cold dark matter or ΛCDM), dark energy is in the form of a cosmological constant, the expansion will eventually become exponential, with the size of the universe doubling at a constant rate.

If the theory of inflation is true, the universe went through an episode dominated by a different form of dark energy in the first moments of the Big Bang; but inflation ended, indicating an equation of state much more complicated than those assumed so far for present-day dark energy. It is possible that the dark energy equation of state could change again resulting in an event that would have consequences which are extremely difficult to parametrize or predict.[citation needed]

Future history edit

In the 1970s, the future of an expanding universe was studied by the astrophysicist Jamal Islam[12] and the physicist Freeman Dyson.[13] Then, in their 1999 book The Five Ages of the Universe, the astrophysicists Fred Adams and Gregory Laughlin divided the past and future history of an expanding universe into five eras. The first, the Primordial Era, is the time in the past just after the Big Bang when stars had not yet formed. The second, the Stelliferous Era, includes the present day and all of the stars and galaxies now seen. It is the time during which stars form from collapsing clouds of gas. In the subsequent Degenerate Era, the stars will have burnt out, leaving all stellar-mass objects as stellar remnantswhite dwarfs, neutron stars, and black holes. In the Black Hole Era, white dwarfs, neutron stars, and other smaller astronomical objects have been destroyed by proton decay, leaving only black holes. Finally, in the Dark Era, even black holes have disappeared, leaving only a dilute gas of photons and leptons.[14]

This future history and the timeline below assume the continued expansion of the universe. If space in the universe begins to contract, subsequent events in the timeline may not occur because the Big Crunch, the collapse of the universe into a hot, dense state similar to that after the Big Bang, will supervene.[14][15]

Timeline edit

For the past, including the Primordial Era, see Chronology of the universe.
See also: Timeline of the far future

The Stelliferous Era edit

See also: Graphical timeline of the Stelliferous Era
From the present to about 1014 (100 trillion) years after the Big Bang
 
An image of many stars.

The observable universe is currently 1.38×1010 (13.8 billion) years old.[16] This time lies within the Stelliferous Era. About 155 million years after the Big Bang, the first star formed. Since then, stars have formed by the collapse of small, dense core regions in large, cold molecular clouds of hydrogen gas. At first, this produces a protostar, which is hot and bright because of energy generated by gravitational contraction. After the protostar contracts for a while, its core could become hot enough to fuse hydrogen, if it exceeds critical mass, a process called 'stellar ignition' occurs, and its lifetime as a star will properly begin.[14]

Stars of very low mass will eventually exhaust all their fusible hydrogen and then become helium white dwarfs.[17] Stars of low to medium mass, such as our own sun, will expel some of their mass as a planetary nebula and eventually become white dwarfs; more massive stars will explode in a core-collapse supernova, leaving behind neutron stars or black holes.[18] In any case, although some of the star's matter may be returned to the interstellar medium, a degenerate remnant will be left behind whose mass is not returned to the interstellar medium. Therefore, the supply of gas available for star formation is steadily being exhausted.

Milky Way Galaxy and the Andromeda Galaxy merge into one edit

Main article: Andromeda–Milky Way collision
4–8 billion years from now (17.8–21.8 billion years after the Big Bang)
 
An artistic illustration of what it would look like from Earth during the Milky way-Andromeda galaxy collision event.

The Andromeda Galaxy is approximately 2.5 million light years away from our galaxy, the Milky Way galaxy, and they are moving towards each other at approximately 300 kilometers (186 miles) per second. Approximately five billion years from now, or 19 billion years after the Big Bang, the Milky Way and the Andromeda galaxy will collide with one another and merge into one large galaxy based on current evidence. Up until 2012, there was no way to confirm whether the possible collision was going to happen or not.[19] In 2012, researchers came to the conclusion that the collision is definite after using the Hubble Space Telescope between 2002 and 2010 to track the motion of Andromeda.[20] This results in the formation of Milkdromeda (also known as Milkomeda).

22 billion years in the future is the earliest possible end of the Universe in the Big Rip scenario, assuming a model of dark energy with w = −1.5.[21][22]

False vacuum decay may occur in 20 to 30 billion years if the Higgs field is metastable.[23][24][25]

Coalescence of Local Group and galaxies outside the Local Supercluster are no longer accessible edit

1011 (100 billion) to 1012 (1 trillion) years

The galaxies in the Local Group, the cluster of galaxies which includes the Milky Way and the Andromeda Galaxy, are gravitationally bound to each other. It is expected that between 1011 (100 billion) and 1012 (1 trillion) years from now, their orbits will decay and the entire Local Group will merge into one large galaxy.[5]

Assuming that dark energy continues to make the universe expand at an accelerating rate, in about 150 billion years all galaxies outside the Local Supercluster will pass behind the cosmological horizon. It will then be impossible for events in the Local Supercluster to affect other galaxies. Similarly, it will be impossible for events after 150 billion years, as seen by observers in distant galaxies, to affect events in the Local Supercluster.[4] However, an observer in the Local Supercluster will continue to see distant galaxies, but events they observe will become exponentially more redshifted as the galaxy approaches the horizon until time in the distant galaxy seems to stop. The observer in the Local Supercluster never observes events after 150 billion years in their local time, and eventually all light and background radiation lying outside the Local Supercluster will appear to blink out as light becomes so redshifted that its wavelength has become longer than the physical diameter of the horizon.

Technically, it will take an infinitely long time for all causal interaction between the Local Supercluster and this light to cease. However, due to the redshifting explained above, the light will not necessarily be observed for an infinite amount of time, and after 150 billion years, no new causal interaction will be observed.

Therefore, after 150 billion years, intergalactic transportation and communication beyond the Local Supercluster becomes causally impossible.

Luminosities of galaxies begin to diminish edit

8×1011 (800 billion) years

8×1011 (800 billion) years from now, the luminosities of the different galaxies, approximately similar until then to the current ones thanks to the increasing luminosity of the remaining stars as they age, will start to decrease, as the less massive red dwarf stars begin to die as white dwarfs.[26]

 
A image of the local group of galaxies.

Galaxies outside the Local Supercluster are no longer detectable edit

2×1012 (2 trillion) years

2×1012 (2 trillion) years from now, all galaxies outside the Local Supercluster will be redshifted to such an extent that even gamma rays they emit will have wavelengths longer than the size of the observable universe of the time. Therefore, these galaxies will no longer be detectable in any way.[4]

Degenerate Era edit

From 1014 (100 trillion) to 1040 (10 duodecillion) years

By 1014 (100 trillion) years from now, star formation will end,[5] leaving all stellar objects in the form of degenerate remnants. If protons do not decay, stellar-mass objects will disappear more slowly, making this era last longer.

Star formation ceases edit

1012–14 (1–100 trillion) years

By 1014 (100 trillion) years from now, star formation will end. This period, known as the "Degenerate Era", will last until the degenerate remnants finally decay.[27] The least-massive stars take the longest to exhaust their hydrogen fuel (see stellar evolution). Thus, the longest living stars in the universe are low-mass red dwarfs, with a mass of about 0.08 solar masses (M), which have a lifetime of over 1013 (10 trillion) years.[28] Coincidentally, this is comparable to the length of time over which star formation takes place.[5] Once star formation ends and the least-massive red dwarfs exhaust their fuel, nuclear fusion will cease. The low-mass red dwarfs will cool and become black dwarfs.[17] The only objects remaining with more than planetary mass will be brown dwarfs, with mass less than 0.08 M, and degenerate remnants; white dwarfs, produced by stars with initial masses between about 0.08 and 8 solar masses; and neutron stars and black holes, produced by stars with initial masses over 8 M. Most of the mass of this collection, approximately 90%, will be in the form of white dwarfs.[6] In the absence of any energy source, all of these formerly luminous bodies will cool and become faint.

The universe will become extremely dark after the last stars burn out. Even so, there can still be occasional light in the universe. One of the ways the universe can be illuminated is if two carbonoxygen white dwarfs with a combined mass of more than the Chandrasekhar limit of about 1.4 solar masses happen to merge. The resulting object will then undergo runaway thermonuclear fusion, producing a Type Ia supernova and dispelling the darkness of the Degenerate Era for a few weeks. Neutron stars could also collide, forming even brighter supernovae and dispelling up to 6 solar masses of degenerate gas into the interstellar medium. The resulting matter from these supernovae could potentially create new stars.[29][30] If the combined mass is not above the Chandrasekhar limit but is larger than the minimum mass to fuse carbon (about 0.9 M), a carbon star could be produced, with a lifetime of around 106 (1 million) years.[14] Also, if two helium white dwarfs with a combined mass of at least 0.3 M collide, a helium star may be produced, with a lifetime of a few hundred million years.[14] Finally, brown dwarfs could form new stars by colliding with each other to form red dwarf stars, which can survive for 1013 (10 trillion) years,[28][29] or by accreting gas at very slow rates from the remaining interstellar medium until they have enough mass to start hydrogen burning as red dwarfs. This process, at least on white dwarfs, could induce Type Ia supernovae.[31]

Planets fall or are flung from orbits by a close encounter with another star edit

1015 (1 quadrillion) years

Over time, the orbits of planets will decay due to gravitational radiation, or planets will be ejected from their local systems by gravitational perturbations caused by encounters with another stellar remnant.[32]

Stellar remnants escape galaxies or fall into black holes edit

1019 to 1020 (10 to 100 quintillion) years

Over time, objects in a galaxy exchange kinetic energy in a process called dynamical relaxation, making their velocity distribution approach the Maxwell–Boltzmann distribution.[33] Dynamical relaxation can proceed either by close encounters of two stars or by less violent but more frequent distant encounters.[34] In the case of a close encounter, two brown dwarfs or stellar remnants will pass close to each other. When this happens, the trajectories of the objects involved in the close encounter change slightly, in such a way that their kinetic energies are more nearly equal than before. After a large number of encounters, then, lighter objects tend to gain speed while the heavier objects lose it.[14]

Because of dynamical relaxation, some objects will gain just enough energy to reach galactic escape velocity and depart the galaxy, leaving behind a smaller, denser galaxy. Since encounters are more frequent in this denser galaxy, the process then accelerates. The result is that most objects (90% to 99%) are ejected from the galaxy, leaving a small fraction (maybe 1% to 10%) which fall into the central supermassive black hole.[5][14] It has been suggested that the matter of the fallen remnants will form an accretion disk around it that will create a quasar, as long as enough matter is present there.[35]

Possible ionization of matter edit

>1023 years from now

In an expanding universe with decreasing density and non-zero cosmological constant, matter density would reach zero, resulting in most matter except black dwarfs, neutron stars, black holes, and planets ionizing and dissipating at thermal equilibrium.[36]

Future with proton decay edit

The following timeline assumes that protons do decay.

Chance: 1032 (100 nonillion) – 1042 years (1 tredecillion)

The subsequent evolution of the universe depends on the possibility and rate of proton decay. Experimental evidence shows that if the proton is unstable, it has a half-life of at least 1035 years.[37] Some of the Grand Unified theories (GUTs) predict long-term proton instability between 1032 and 1038 years, with the upper bound on standard (non-supersymmetry) proton decay at 1.4×1036 years and an overall upper limit maximum for any proton decay (including supersymmetry models) at 6×1042 years.[38][39] Recent research showing proton lifetime (if unstable) at or exceeding 1036–1037 year range rules out simpler GUTs and most non-supersymmetry models.

Nucleons start to decay edit

See also: Nucleon

Neutrons bound into nuclei are also suspected to decay with a half-life comparable to that of protons. Planets (substellar objects) would decay in a simple cascade process from heavier elements to hydrogen and finally to photons and leptons while radiating energy.[40]

If the proton does not decay at all, then stellar objects would still disappear, but more slowly. See § Future without proton decay below.

Shorter or longer proton half-lives will accelerate or decelerate the process. This means that after 1040 years (the maximum proton half-life used by Adams & Laughlin (1997)), one-half of all baryonic matter will have been converted into gamma ray photons and leptons through proton decay.

All nucleons decay edit

1043 (10 tredecillion) years

Given our assumed half-life of the proton, nucleons (protons and bound neutrons) will have undergone roughly 1,000 half-lives by the time the universe is 1043 years old. This means that there will be roughly 0.51,000 (approximately 10−301) as many nucleons; as there are an estimated 1080 protons currently in the universe,[41] none will remain at the end of the Degenerate Age. Effectively, all baryonic matter will have been changed into photons and leptons. Some models predict the formation of stable positronium atoms with diameters greater than the observable universe's current diameter (roughly 6 ×1034 metres)[42] in 1098 years, and that these will in turn decay to gamma radiation in 10176 years.[5][6]

 
The supermassive black holes are all that remain of galaxies once all protons decay, but even these giants are not immortal.

If protons decay on higher-order nuclear processes edit

Chance: 1076 to 10220 years

If the proton does not decay according to the theories described above, then the Degenerate Era will last longer, and will overlap or surpass the Black Hole Era. On a time scale of 1065 years solid matter is theorized to potentially rearrange its atoms and molecules via quantum tunneling, and may behave as liquid and become smooth spheres due to diffusion and gravity.[13] Degenerate stellar objects can potentially still experience proton decay, for example via processes involving the Adler–Bell–Jackiw anomaly, virtual black holes, or higher-dimension supersymmetry possibly with a half-life of under 10220 years.[5]

>10145 years from now

2018 estimate of Standard Model lifetime before collapse of a false vacuum; 95% confidence interval is 1065 to 10725 years due in part to uncertainty about the top quark mass.[43]

>10200 years from now

Although protons are stable in standard model physics, a quantum anomaly may exist on the electroweak level, which can cause groups of baryons (protons and neutrons) to annihilate into antileptons via the sphaleron transition.[44] Such baryon/lepton violations have a number of 3 and can only occur in multiples or groups of three baryons, which can restrict or prohibit such events. No experimental evidence of sphalerons has yet been observed at low energy levels, though they are believed to occur regularly at high energies and temperatures.

 
The photon, electron, positron, and neutrino are now the final remnants of the universe as the last of the supermassive black holes evaporate.

Black Hole Era edit

1043 (10 tredecillion) years to approximately 10100 (1 googol) years, up to 10110 years for the largest supermassive black holes

After 1043 years, black holes will dominate the universe. They will slowly evaporate via Hawking radiation.[5] A black hole with a mass of around 1 M will vanish in around 2×1064 years. As the lifetime of a black hole is proportional to the cube of its mass, more massive black holes take longer to decay. A supermassive black hole with a mass of 1011 (100 billion) M will evaporate in around 2×1093 years.[45]

The largest black holes in the universe are predicted to continue to grow. Larger black holes of up to 1014 (100 trillion) M may form during the collapse of superclusters of galaxies. Even these would evaporate over a timescale of 10109[46] to 10110 years.

Hawking radiation has a thermal spectrum. During most of a black hole's lifetime, the radiation has a low temperature and is mainly in the form of massless particles such as photons and hypothetical gravitons. As the black hole's mass decreases, its temperature increases, becoming comparable to the Sun's by the time the black hole mass has decreased to 1019 kilograms. The hole then provides a temporary source of light during the general darkness of the Black Hole Era. During the last stages of its evaporation, a black hole will emit not only massless particles, but also heavier particles, such as electrons, positrons, protons, and antiprotons.[14]

Dark Era and Photon Age edit

From 10100 years (10 duotrigintillion years or 1 googol years) and beyond

After all the black holes have evaporated (and after all the ordinary matter made of protons has disintegrated, if protons are unstable), the universe will be nearly empty. Photons, leptons, baryons, neutrinos, electrons, and positrons will fly from place to place, hardly ever encountering each other. Gravitationally, the universe will be dominated by dark matter, electrons, and positrons (not protons).[47]

By this era, with only very diffuse matter remaining, activity in the universe will eventually tail off dramatically (compared with previous eras), with very low energy levels and very large time scales, with events taking a very long time to happen if they ever happen at all. Electrons and positrons drifting through space will encounter one another and occasionally form positronium atoms. These structures are unstable, however, and their constituent particles must eventually annihilate. However, most electrons and positrons will remain unbound.[48] Other low-level annihilation events will also take place, albeit very, very slowly. The universe now reaches an extremely low-energy state.

Future without proton decay edit

If protons do not decay, stellar-mass objects will still become black holes, although even more slowly. The following timeline that assumes proton decay does not take place.

10161 years from now

2018 estimate of Standard Model lifetime before collapse of a false vacuum; 95% confidence interval is 1065 to 101383 years due in part to uncertainty about the top quark mass.[43][note 1]

Degenerate Era edit

Matter decays into iron edit

101100 to 1032000 years from now
 
All matter will slowly decay into iron which will take from 101100 to 1032000 years.

In 101500 years, cold fusion occurring via quantum tunneling should make the light nuclei in stellar-mass objects fuse into iron-56 nuclei (see isotopes of iron). Fission and alpha particle emission should make heavy nuclei also decay to iron, leaving stellar-mass objects as cold spheres of iron, called iron stars.[13] Before this happens, however, in some black dwarfs the process is expected to lower their Chandrasekhar limit resulting in a supernova in 101100 years. Non-degenerate silicon has been calculated to tunnel to iron in approximately 1032000 years.[49]

Black Hole Era edit

Collapse of iron stars to black holes edit

101030 to 1010105 years from now

Quantum tunneling should also turn large objects into black holes, which (on these timescales) will instantaneously evaporate into subatomic particles. Depending on the assumptions made, the time this takes to happen can be calculated as from 101026 years to 101076 years. Quantum tunneling may also make iron stars collapse into neutron stars in around 101076 years.[13]

Dark Era (without proton decay) edit

1010105 to 1010120 years from now

With black holes having evaporated, nearly all baryonic matter will have now decayed into subatomic particles (electrons, neutrons, protons, and quarks). The universe is now an almost pure vacuum (possibly accompanied with the presence of a false vacuum). The expansion of the universe slowly causes itself to cool down to absolute zero The universe now reaches an even lower energy state than the earlier one mentioned.[50][51]

Beyond edit

See also: Ultimate fate of the universe
Beyond 102500 years if proton decay occurs, or 101076 years without proton decay

Whatever event happens beyond this era is highly speculative. It is possible that a Big Rip event may occur far off into the future.[52][53] This singularity would take place at a finite scale factor.

If the current vacuum state is a false vacuum, the vacuum may decay into an even lower-energy state.[54]

Presumably, extreme low-energy states imply that localized quantum events become major macroscopic phenomena rather than negligible microscopic events because even the smallest perturbations make the biggest difference in this era, so there is no telling what will or might happen to space or time. It is perceived that the laws of "macro-physics" will break down, and the laws of quantum physics will prevail.[8]

The universe could possibly avoid eternal heat death through random quantum tunneling and quantum fluctuations, given the non-zero probability of producing a new Big Bang creating a new universe in roughly 10101056 years.[55]

Over an infinite amount of time, there could also be a spontaneous entropy decrease, by a Poincaré recurrence or through thermal fluctuations (see also fluctuation theorem).[56][57][58]

Massive black dwarfs could also potentially explode into supernovae after up to 1032000 years, assuming protons do not decay.[59]

The possibilities above are based on a simple form of dark energy. However, the physics of dark energy are still a very speculative area of research, and the actual form of dark energy could be much more complex.

Graphical timeline edit

Main article: Graphical timeline from Big Bang to Heat Death
See also: Graphical timeline of the universe and Graphical timeline of the Big Bang
Logarithmic scale

See also edit

Notes edit

  1. ^ Manuscript was updated after publication; lifetime numbers are taken from the latest revision at https://arxiv.org/abs/1707.08124.

References edit

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External links edit

  • A Journey to the End of Time (4K) on YouTube by melodysheep

January 01, 1970
future, expanding, universe, current, observations, suggest, that, expansion, universe, will, continue, forever, prevailing, theory, that, universe, will, cool, expands, eventually, becoming, cold, sustain, life, this, reason, this, future, scenario, once, pop. Current observations suggest that the expansion of the universe will continue forever The prevailing theory is that the universe will cool as it expands eventually becoming too cold to sustain life For this reason this future scenario once popularly called Heat Death is now known as the Big Chill or Big Freeze 1 2 If dark energy represented by the cosmological constant a constant energy density filling space homogeneously 3 or scalar fields such as quintessence or moduli dynamic quantities whose energy density can vary in time and space accelerates the expansion of the universe then the space between clusters of galaxies will grow at an increasing rate Redshift will stretch ancient incoming photons even gamma rays to undetectably long wavelengths and low energies 4 Stars are expected to form normally for 1012 to 1014 1 100 trillion years but eventually the supply of gas needed for star formation will be exhausted As existing stars run out of fuel and cease to shine the universe will slowly and inexorably grow darker 5 6 According to theories that predict proton decay the stellar remnants left behind will disappear leaving behind only black holes which themselves eventually disappear as they emit Hawking radiation 7 Ultimately if the universe reaches thermodynamic equilibrium a state in which the temperature approaches a uniform value no further work will be possible resulting in a final heat death of the universe 8 Contents 1 Cosmology 2 Future history 3 Timeline 3 1 The Stelliferous Era 3 1 1 Milky Way Galaxy and the Andromeda Galaxy merge into one 3 1 2 Coalescence of Local Group and galaxies outside the Local Supercluster are no longer accessible 3 1 3 Luminosities of galaxies begin to diminish 3 1 4 Galaxies outside the Local Supercluster are no longer detectable 3 2 Degenerate Era 3 2 1 Star formation ceases 3 2 2 Planets fall or are flung from orbits by a close encounter with another star 3 2 3 Stellar remnants escape galaxies or fall into black holes 3 2 4 Possible ionization of matter 4 Future with proton decay 4 1 Nucleons start to decay 4 2 All nucleons decay 4 3 If protons decay on higher order nuclear processes 4 4 Black Hole Era 4 5 Dark Era and Photon Age 5 Future without proton decay 5 1 Degenerate Era 5 1 1 Matter decays into iron 5 2 Black Hole Era 5 2 1 Collapse of iron stars to black holes 5 3 Dark Era without proton decay 6 Beyond 7 Graphical timeline 8 See also 9 Notes 10 References 11 External linksCosmology editInfinite expansion does not determine the overall spatial curvature of the universe It can be open with negative spatial curvature flat or closed positive spatial curvature although if it is closed sufficient dark energy must be present to counteract the gravitational forces or else the universe will end in a Big Crunch 9 Observations of the Cosmic microwave background by the Wilkinson Microwave Anisotropy Probe and the Planck mission suggest that the universe is spatially flat and has a significant amount of dark energy 10 11 In this case the universe might continue to expand at an accelerating rate The acceleration of the universe s expansion has also been confirmed by observations of distant supernovae 9 If as in the concordance model of physical cosmology Lambda cold dark matter or LCDM dark energy is in the form of a cosmological constant the expansion will eventually become exponential with the size of the universe doubling at a constant rate If the theory of inflation is true the universe went through an episode dominated by a different form of dark energy in the first moments of the Big Bang but inflation ended indicating an equation of state much more complicated than those assumed so far for present day dark energy It is possible that the dark energy equation of state could change again resulting in an event that would have consequences which are extremely difficult to parametrize or predict citation needed Future history editIn the 1970s the future of an expanding universe was studied by the astrophysicist Jamal Islam 12 and the physicist Freeman Dyson 13 Then in their 1999 book The Five Ages of the Universe the astrophysicists Fred Adams and Gregory Laughlin divided the past and future history of an expanding universe into five eras The first the Primordial Era is the time in the past just after the Big Bang when stars had not yet formed The second the Stelliferous Era includes the present day and all of the stars and galaxies now seen It is the time during which stars form from collapsing clouds of gas In the subsequent Degenerate Era the stars will have burnt out leaving all stellar mass objects as stellar remnants white dwarfs neutron stars and black holes In the Black Hole Era white dwarfs neutron stars and other smaller astronomical objects have been destroyed by proton decay leaving only black holes Finally in the Dark Era even black holes have disappeared leaving only a dilute gas of photons and leptons 14 This future history and the timeline below assume the continued expansion of the universe If space in the universe begins to contract subsequent events in the timeline may not occur because the Big Crunch the collapse of the universe into a hot dense state similar to that after the Big Bang will supervene 14 15 Timeline editFor the past including the Primordial Era see Chronology of the universe See also Timeline of the far future The Stelliferous Era edit See also Graphical timeline of the Stelliferous Era From the present to about 1014 100 trillion years after the Big Bang nbsp An image of many stars The observable universe is currently 1 38 1010 13 8 billion years old 16 This time lies within the Stelliferous Era About 155 million years after the Big Bang the first star formed Since then stars have formed by the collapse of small dense core regions in large cold molecular clouds of hydrogen gas At first this produces a protostar which is hot and bright because of energy generated by gravitational contraction After the protostar contracts for a while its core could become hot enough to fuse hydrogen if it exceeds critical mass a process called stellar ignition occurs and its lifetime as a star will properly begin 14 Stars of very low mass will eventually exhaust all their fusible hydrogen and then become helium white dwarfs 17 Stars of low to medium mass such as our own sun will expel some of their mass as a planetary nebula and eventually become white dwarfs more massive stars will explode in a core collapse supernova leaving behind neutron stars or black holes 18 In any case although some of the star s matter may be returned to the interstellar medium a degenerate remnant will be left behind whose mass is not returned to the interstellar medium Therefore the supply of gas available for star formation is steadily being exhausted Milky Way Galaxy and the Andromeda Galaxy merge into one edit Main article Andromeda Milky Way collision 4 8 billion years from now 17 8 21 8 billion years after the Big Bang nbsp An artistic illustration of what it would look like from Earth during the Milky way Andromeda galaxy collision event The Andromeda Galaxy is approximately 2 5 million light years away from our galaxy the Milky Way galaxy and they are moving towards each other at approximately 300 kilometers 186 miles per second Approximately five billion years from now or 19 billion years after the Big Bang the Milky Way and the Andromeda galaxy will collide with one another and merge into one large galaxy based on current evidence Up until 2012 there was no way to confirm whether the possible collision was going to happen or not 19 In 2012 researchers came to the conclusion that the collision is definite after using the Hubble Space Telescope between 2002 and 2010 to track the motion of Andromeda 20 This results in the formation of Milkdromeda also known as Milkomeda 22 billion years in the future is the earliest possible end of the Universe in the Big Rip scenario assuming a model of dark energy with w 1 5 21 22 False vacuum decay may occur in 20 to 30 billion years if the Higgs field is metastable 23 24 25 Coalescence of Local Group and galaxies outside the Local Supercluster are no longer accessible edit 1011 100 billion to 1012 1 trillion years The galaxies in the Local Group the cluster of galaxies which includes the Milky Way and the Andromeda Galaxy are gravitationally bound to each other It is expected that between 1011 100 billion and 1012 1 trillion years from now their orbits will decay and the entire Local Group will merge into one large galaxy 5 Assuming that dark energy continues to make the universe expand at an accelerating rate in about 150 billion years all galaxies outside the Local Supercluster will pass behind the cosmological horizon It will then be impossible for events in the Local Supercluster to affect other galaxies Similarly it will be impossible for events after 150 billion years as seen by observers in distant galaxies to affect events in the Local Supercluster 4 However an observer in the Local Supercluster will continue to see distant galaxies but events they observe will become exponentially more redshifted as the galaxy approaches the horizon until time in the distant galaxy seems to stop The observer in the Local Supercluster never observes events after 150 billion years in their local time and eventually all light and background radiation lying outside the Local Supercluster will appear to blink out as light becomes so redshifted that its wavelength has become longer than the physical diameter of the horizon Technically it will take an infinitely long time for all causal interaction between the Local Supercluster and this light to cease However due to the redshifting explained above the light will not necessarily be observed for an infinite amount of time and after 150 billion years no new causal interaction will be observed Therefore after 150 billion years intergalactic transportation and communication beyond the Local Supercluster becomes causally impossible Luminosities of galaxies begin to diminish edit 8 1011 800 billion years 8 1011 800 billion years from now the luminosities of the different galaxies approximately similar until then to the current ones thanks to the increasing luminosity of the remaining stars as they age will start to decrease as the less massive red dwarf stars begin to die as white dwarfs 26 nbsp A image of the local group of galaxies Galaxies outside the Local Supercluster are no longer detectable edit 2 1012 2 trillion years 2 1012 2 trillion years from now all galaxies outside the Local Supercluster will be redshifted to such an extent that even gamma rays they emit will have wavelengths longer than the size of the observable universe of the time Therefore these galaxies will no longer be detectable in any way 4 Degenerate Era edit From 1014 100 trillion to 1040 10 duodecillion years By 1014 100 trillion years from now star formation will end 5 leaving all stellar objects in the form of degenerate remnants If protons do not decay stellar mass objects will disappear more slowly making this era last longer Star formation ceases edit 1012 14 1 100 trillion years By 1014 100 trillion years from now star formation will end This period known as the Degenerate Era will last until the degenerate remnants finally decay 27 The least massive stars take the longest to exhaust their hydrogen fuel see stellar evolution Thus the longest living stars in the universe are low mass red dwarfs with a mass of about 0 08 solar masses M which have a lifetime of over 1013 10 trillion years 28 Coincidentally this is comparable to the length of time over which star formation takes place 5 Once star formation ends and the least massive red dwarfs exhaust their fuel nuclear fusion will cease The low mass red dwarfs will cool and become black dwarfs 17 The only objects remaining with more than planetary mass will be brown dwarfs with mass less than 0 08 M and degenerate remnants white dwarfs produced by stars with initial masses between about 0 08 and 8 solar masses and neutron stars and black holes produced by stars with initial masses over 8 M Most of the mass of this collection approximately 90 will be in the form of white dwarfs 6 In the absence of any energy source all of these formerly luminous bodies will cool and become faint The universe will become extremely dark after the last stars burn out Even so there can still be occasional light in the universe One of the ways the universe can be illuminated is if two carbon oxygen white dwarfs with a combined mass of more than the Chandrasekhar limit of about 1 4 solar masses happen to merge The resulting object will then undergo runaway thermonuclear fusion producing a Type Ia supernova and dispelling the darkness of the Degenerate Era for a few weeks Neutron stars could also collide forming even brighter supernovae and dispelling up to 6 solar masses of degenerate gas into the interstellar medium The resulting matter from these supernovae could potentially create new stars 29 30 If the combined mass is not above the Chandrasekhar limit but is larger than the minimum mass to fuse carbon about 0 9 M a carbon star could be produced with a lifetime of around 106 1 million years 14 Also if two helium white dwarfs with a combined mass of at least 0 3 M collide a helium star may be produced with a lifetime of a few hundred million years 14 Finally brown dwarfs could form new stars by colliding with each other to form red dwarf stars which can survive for 1013 10 trillion years 28 29 or by accreting gas at very slow rates from the remaining interstellar medium until they have enough mass to start hydrogen burning as red dwarfs This process at least on white dwarfs could induce Type Ia supernovae 31 Planets fall or are flung from orbits by a close encounter with another star edit 1015 1 quadrillion years Over time the orbits of planets will decay due to gravitational radiation or planets will be ejected from their local systems by gravitational perturbations caused by encounters with another stellar remnant 32 Stellar remnants escape galaxies or fall into black holes edit 1019 to 1020 10 to 100 quintillion years Over time objects in a galaxy exchange kinetic energy in a process called dynamical relaxation making their velocity distribution approach the Maxwell Boltzmann distribution 33 Dynamical relaxation can proceed either by close encounters of two stars or by less violent but more frequent distant encounters 34 In the case of a close encounter two brown dwarfs or stellar remnants will pass close to each other When this happens the trajectories of the objects involved in the close encounter change slightly in such a way that their kinetic energies are more nearly equal than before After a large number of encounters then lighter objects tend to gain speed while the heavier objects lose it 14 Because of dynamical relaxation some objects will gain just enough energy to reach galactic escape velocity and depart the galaxy leaving behind a smaller denser galaxy Since encounters are more frequent in this denser galaxy the process then accelerates The result is that most objects 90 to 99 are ejected from the galaxy leaving a small fraction maybe 1 to 10 which fall into the central supermassive black hole 5 14 It has been suggested that the matter of the fallen remnants will form an accretion disk around it that will create a quasar as long as enough matter is present there 35 Possible ionization of matter edit gt 1023 years from now In an expanding universe with decreasing density and non zero cosmological constant matter density would reach zero resulting in most matter except black dwarfs neutron stars black holes and planets ionizing and dissipating at thermal equilibrium 36 Future with proton decay editThe following timeline assumes that protons do decay Chance 1032 100 nonillion 1042 years 1 tredecillion The subsequent evolution of the universe depends on the possibility and rate of proton decay Experimental evidence shows that if the proton is unstable it has a half life of at least 1035 years 37 Some of the Grand Unified theories GUTs predict long term proton instability between 1032 and 1038 years with the upper bound on standard non supersymmetry proton decay at 1 4 1036 years and an overall upper limit maximum for any proton decay including supersymmetry models at 6 1042 years 38 39 Recent research showing proton lifetime if unstable at or exceeding 1036 1037 year range rules out simpler GUTs and most non supersymmetry models Nucleons start to decay edit See also Nucleon Neutrons bound into nuclei are also suspected to decay with a half life comparable to that of protons Planets substellar objects would decay in a simple cascade process from heavier elements to hydrogen and finally to photons and leptons while radiating energy 40 If the proton does not decay at all then stellar objects would still disappear but more slowly See Future without proton decay below Shorter or longer proton half lives will accelerate or decelerate the process This means that after 1040 years the maximum proton half life used by Adams amp Laughlin 1997 one half of all baryonic matter will have been converted into gamma ray photons and leptons through proton decay All nucleons decay edit 1043 10 tredecillion years Given our assumed half life of the proton nucleons protons and bound neutrons will have undergone roughly 1 000 half lives by the time the universe is 1043 years old This means that there will be roughly 0 51 000 approximately 10 301 as many nucleons as there are an estimated 1080 protons currently in the universe 41 none will remain at the end of the Degenerate Age Effectively all baryonic matter will have been changed into photons and leptons Some models predict the formation of stable positronium atoms with diameters greater than the observable universe s current diameter roughly 6 1034 metres 42 in 1098 years and that these will in turn decay to gamma radiation in 10176 years 5 6 nbsp The supermassive black holes are all that remain of galaxies once all protons decay but even these giants are not immortal If protons decay on higher order nuclear processes edit Chance 1076 to 10220 years If the proton does not decay according to the theories described above then the Degenerate Era will last longer and will overlap or surpass the Black Hole Era On a time scale of 1065 years solid matter is theorized to potentially rearrange its atoms and molecules via quantum tunneling and may behave as liquid and become smooth spheres due to diffusion and gravity 13 Degenerate stellar objects can potentially still experience proton decay for example via processes involving the Adler Bell Jackiw anomaly virtual black holes or higher dimension supersymmetry possibly with a half life of under 10220 years 5 gt 10145 years from now 2018 estimate of Standard Model lifetime before collapse of a false vacuum 95 confidence interval is 1065 to 10725 years due in part to uncertainty about the top quark mass 43 gt 10200 years from now Although protons are stable in standard model physics a quantum anomaly may exist on the electroweak level which can cause groups of baryons protons and neutrons to annihilate into antileptons via the sphaleron transition 44 Such baryon lepton violations have a number of 3 and can only occur in multiples or groups of three baryons which can restrict or prohibit such events No experimental evidence of sphalerons has yet been observed at low energy levels though they are believed to occur regularly at high energies and temperatures nbsp The photon electron positron and neutrino are now the final remnants of the universe as the last of the supermassive black holes evaporate Black Hole Era edit 1043 10 tredecillion years to approximately 10100 1 googol years up to 10110 years for the largest supermassive black holes After 1043 years black holes will dominate the universe They will slowly evaporate via Hawking radiation 5 A black hole with a mass of around 1 M will vanish in around 2 1064 years As the lifetime of a black hole is proportional to the cube of its mass more massive black holes take longer to decay A supermassive black hole with a mass of 1011 100 billion M will evaporate in around 2 1093 years 45 The largest black holes in the universe are predicted to continue to grow Larger black holes of up to 1014 100 trillion M may form during the collapse of superclusters of galaxies Even these would evaporate over a timescale of 10109 46 to 10110 years Hawking radiation has a thermal spectrum During most of a black hole s lifetime the radiation has a low temperature and is mainly in the form of massless particles such as photons and hypothetical gravitons As the black hole s mass decreases its temperature increases becoming comparable to the Sun s by the time the black hole mass has decreased to 1019 kilograms The hole then provides a temporary source of light during the general darkness of the Black Hole Era During the last stages of its evaporation a black hole will emit not only massless particles but also heavier particles such as electrons positrons protons and antiprotons 14 Dark Era and Photon Age edit From 10100 years 10 duotrigintillion years or 1 googol years and beyond After all the black holes have evaporated and after all the ordinary matter made of protons has disintegrated if protons are unstable the universe will be nearly empty Photons leptons baryons neutrinos electrons and positrons will fly from place to place hardly ever encountering each other Gravitationally the universe will be dominated by dark matter electrons and positrons not protons 47 By this era with only very diffuse matter remaining activity in the universe will eventually tail off dramatically compared with previous eras with very low energy levels and very large time scales with events taking a very long time to happen if they ever happen at all Electrons and positrons drifting through space will encounter one another and occasionally form positronium atoms These structures are unstable however and their constituent particles must eventually annihilate However most electrons and positrons will remain unbound 48 Other low level annihilation events will also take place albeit very very slowly The universe now reaches an extremely low energy state Future without proton decay editThis section needs expansion You can help by adding to it July 2020 If protons do not decay stellar mass objects will still become black holes although even more slowly The following timeline that assumes proton decay does not take place 10161 years from now 2018 estimate of Standard Model lifetime before collapse of a false vacuum 95 confidence interval is 1065 to 101383 years due in part to uncertainty about the top quark mass 43 note 1 Degenerate Era edit Matter decays into iron edit 101100 to 1032000 years from now nbsp All matter will slowly decay into iron which will take from 101100 to 1032000 years In 101500 years cold fusion occurring via quantum tunneling should make the light nuclei in stellar mass objects fuse into iron 56 nuclei see isotopes of iron Fission and alpha particle emission should make heavy nuclei also decay to iron leaving stellar mass objects as cold spheres of iron called iron stars 13 Before this happens however in some black dwarfs the process is expected to lower their Chandrasekhar limit resulting in a supernova in 101100 years Non degenerate silicon has been calculated to tunnel to iron in approximately 1032000 years 49 Black Hole Era edit Collapse of iron stars to black holes edit 101030 to 1010105 years from now Quantum tunneling should also turn large objects into black holes which on these timescales will instantaneously evaporate into subatomic particles Depending on the assumptions made the time this takes to happen can be calculated as from 101026 years to 101076 years Quantum tunneling may also make iron stars collapse into neutron stars in around 101076 years 13 Dark Era without proton decay edit 1010105 to 1010120 years from now With black holes having evaporated nearly all baryonic matter will have now decayed into subatomic particles electrons neutrons protons and quarks The universe is now an almost pure vacuum possibly accompanied with the presence of a false vacuum The expansion of the universe slowly causes itself to cool down to absolute zero The universe now reaches an even lower energy state than the earlier one mentioned 50 51 Beyond editSee also Ultimate fate of the universe Beyond 102500 years if proton decay occurs or 101076 years without proton decay Whatever event happens beyond this era is highly speculative It is possible that a Big Rip event may occur far off into the future 52 53 This singularity would take place at a finite scale factor If the current vacuum state is a false vacuum the vacuum may decay into an even lower energy state 54 Presumably extreme low energy states imply that localized quantum events become major macroscopic phenomena rather than negligible microscopic events because even the smallest perturbations make the biggest difference in this era so there is no telling what will or might happen to space or time It is perceived that the laws of macro physics will break down and the laws of quantum physics will prevail 8 The universe could possibly avoid eternal heat death through random quantum tunneling and quantum fluctuations given the non zero probability of producing a new Big Bang creating a new universe in roughly 10101056 years 55 Over an infinite amount of time there could also be a spontaneous entropy decrease by a Poincare recurrence or through thermal fluctuations see also fluctuation theorem 56 57 58 Massive black dwarfs could also potentially explode into supernovae after up to 1032000 years assuming protons do not decay 59 The possibilities above are based on a simple form of dark energy However the physics of dark energy are still a very speculative area of research and the actual form of dark energy could be much more complex Graphical timeline editMain article Graphical timeline from Big Bang to Heat Death See also Graphical timeline of the universe and Graphical timeline of the Big BangSee also editBig Bounce Model for the origin of the universe Big Crunch Theoretical scenario for the ultimate fate of the universe Big Rip Cosmological model Chronology of the universe History and future of the universe Cyclic model Cosmological models involving indefinite self sustaining cycles Dyson s eternal intelligence Hypothetical concept in astrophysics Final anthropic principle American physicistPages displaying short descriptions of redirect targets Graphical timeline from Big Bang to Heat Death Visual representation of the universe s past present and future This timeline uses the double logarithmic scale for comparison with the graphical timeline included in this article Graphical timeline of the Big Bang Logarithmic chronology of the event that began the Universe Graphical timeline of the Stelliferous Era Graphical timeline of the universe Visual timeline of the universe This timeline uses the more intuitive linear time for comparison with this article The Last Question A short story by Isaac Asimov which considers the inevitable oncome of heat death in the universe and how it may be reversed Heat death of the universe Possible fate of the universe Timeline of the far future Scientific projections regarding the far future Ultimate fate of the universe Theories about the end of the universeNotes edit Manuscript was updated after publication lifetime numbers are taken from the latest revision at https arxiv org abs 1707 08124 References edit Adams Fred C Laughlin Gregory A DYING UNIVERSE The Long Term Fate and Evolution of Astrophysical Objects PDF Archived from the original PDF on 17 May 2021 What Is the Ultimate Fate of the Universe WMAP s Universe NASA 29 June 2015 Retrieved 19 February 2023 Sean Carroll 2001 The cosmological constant Living Reviews in Relativity 4 1 1 arXiv astro ph 0004075 Bibcode 2001LRR 4 1C doi 10 12942 lrr 2001 1 PMC 5256042 PMID 28179856 Archived from the original on 13 October 2006 Retrieved 28 September 2006 a b c Krauss Lawrence M Starkman Glenn D 2000 Life the Universe and Nothing Life and Death in an Ever expanding Universe Astrophysical Journal 531 1 22 30 arXiv astro ph 9902189 Bibcode 2000ApJ 531 22K doi 10 1086 308434 S2CID 18442980 a b c d e f g h Adams Fred C Laughlin Gregory 1997 A dying universe the long term fate and evolution of astrophysical objects Reviews of Modern Physics 69 2 337 372 arXiv astro ph 9701131 Bibcode 1997RvMP 69 337A doi 10 1103 RevModPhys 69 337 S2CID 12173790 a b c Adams amp Laughlin 1997 IIE Adams amp Laughlin 1997 IV a b Adams amp Laughlin 1997 VID a b Chapter 7 Calibrating the Cosmos Frank Levin New York Springer 2006 ISBN 0 387 30778 8 Five Year Wilkinson Microwave Anisotropy Probe WMAP Observations Data Processing Sky Maps and Basic Results G Hinshaw et al The Astrophysical Journal Supplement Series 2008 submitted arXiv 0803 0732 Bibcode 2008arXiv0803 0732H Planck Collaboration et al 1 September 2016 Planck 2015 results XIII Cosmological parameters Astronomy and Astrophysics 594 A13 arXiv 1502 01589 Bibcode 2016A amp A 594A 13P doi 10 1051 0004 6361 201525830 Possible Ultimate Fate of the Universe Jamal N Islam Quarterly Journal of the Royal Astronomical Society 18 March 1977 pp 3 8 Bibcode 1977QJRAS 18 3I a b c d Dyson Freeman J 1979 Time without end Physics and biology in an open universe Reviews of Modern Physics 51 3 447 460 Bibcode 1979RvMP 51 447D doi 10 1103 RevModPhys 51 447 a b c d e f g h The Five Ages of the Universe Fred Adams and Greg Laughlin New York The Free Press 1999 ISBN 0 684 85422 8 Adams amp Laughlin 1997 VA Planck collaboration 2013 Planck 2013 results XVI Cosmological parameters Astronomy amp Astrophysics 571 A16 arXiv 1303 5076 Bibcode 2014A amp A 571A 16P doi 10 1051 0004 6361 201321591 S2CID 118349591 a b Laughlin Gregory Bodenheimer Peter Adams Fred C 1997 The End of the Main Sequence The Astrophysical Journal 482 1 420 432 Bibcode 1997ApJ 482 420L doi 10 1086 304125 Heger A Fryer C L Woosley S E Langer N Hartmann D H 2003 How Massive Single Stars End Their Life Astrophysical Journal 591 1 288 300 arXiv astro ph 0212469 Bibcode 2003ApJ 591 288H doi 10 1086 375341 S2CID 59065632 van der Marel G et al 2012 The M31 Velocity Vector III Future Milky Way M31 M33 Orbital Evolution Merging and Fate of the Sun The Astrophysical Journal 753 1 9 arXiv 1205 6865 Bibcode 2012ApJ 753 9V doi 10 1088 0004 637X 753 1 9 S2CID 53071454 Cowen R 31 May 2012 Andromeda on collision course with the Milky Way Nature doi 10 1038 nature 2012 10765 S2CID 124815138 Universe may end in a Big Rip CERN Courier 30 April 2003 Siegel Ethan Ask Ethan Could The Universe Be Torn Apart In A Big Rip Forbes Crane Leah Physicists have a massive problem as Higgs boson refuses to misbehave New Scientist The Higgs boson makes the universe stable just Coincidence New Scientist Death by Higgs rids cosmos of space brain threat New Scientist Adams F C Graves G J M Laughlin G December 2004 Garcia Segura G Tenorio Tagle G Franco J Yorke eds Gravitational Collapse From Massive Stars to Planets First Astrophysics meeting of the Observatorio Astronomico Nacional A meeting to celebrate Peter Bodenheimer for his outstanding contributions to Astrophysics Red Dwarfs and the End of the Main Sequence Revista Mexicana de Astronomia y Astrofisica Serie de Conferencias 22 46 149 Bibcode 2004RMxAC 22 46A See Fig 3 Adams amp Laughlin 1997 III IV a b Adams amp Laughlin 1997 IIA and Figure 1 a b Adams amp Laughlin 1997 IIIC Richmond M The Future of the Universe hysics 420 Rochester Institute of Technology Retrieved 19 February 2023 Brown Dwarf Accretion Nonconventional Star Formation over Very Long Timescales Cirkovic M M 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Doris C Teplitz Vigdor L 1983 The Future of the Universe Scientific American 248 3 90 101 doi 10 1038 scientificamerican0383 90 JSTOR 24968855 via JSTOR Caldwell Robert R Kamionkowski Marc Weinberg Nevin N 2003 Phantom energy and cosmic doomsday Phys Rev Lett 91 7 071301 arXiv astro ph 0302506 Bibcode 2003PhRvL 91g1301C doi 10 1103 PhysRevLett 91 071301 PMID 12935004 S2CID 119498512 Bouhmadi Lopez Mariam Gonzalez Diaz Pedro F Martin Moruno Prado 2008 Worse than a big rip Physics Letters B 659 1 2 1 5 arXiv gr qc 0612135 Bibcode 2008PhLB 659 1B doi 10 1016 j physletb 2007 10 079 S2CID 119487735 Adams amp Laughlin 1997 VE Carroll Sean M Chen Jennifer 2004 Spontaneous Inflation and Origin of the Arrow of Time arXiv hep th 0410270 Tegmark Max 2003 Parallel Universes Scientific American 288 5 40 51 arXiv astro ph 0302131 Bibcode 2003SciAm 288e 40T doi 10 1038 scientificamerican0503 40 Werlang T Ribeiro G A P Rigolin Gustavo 2013 Interplay between quantum phase transitions and the behavior 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