- Relationship to age of the universe
- Hubble limit as an event horizon
- See also
- References
- External links
In cosmology, a Hubble volume or Hubble sphere is a spherical region of the observable universe surrounding an observer beyond which objects recede from that observer at a rate greater than the speed of light due to the expansion of the Universe.[1] The Hubble volume is approximately equal to 1031 cubic light years.
The proper radius of a Hubble sphere (known as the Hubble radius or the Hubble length) is 
, where 
is the speed of light and 
is the Hubble constant. The surface of a Hubble sphere is called the microphysical horizon,[2] the Hubble surface, or the Hubble limit.
More generally, the term "Hubble volume" can be applied to any region of space with a volume of order 
.
However, the term is also frequently (but mistakenly) used as a synonym for the observable universe; the latter is larger than the Hubble volume.[3][4]
Relationship to age of the universe
The Hubble length is 14.4 billion light years in the standard cosmological model, somewhat larger than times the age of the universe, 13.8 billion years.
Hubble limit as an event horizon
For objects at the Hubble limit the space between us and the object of interest has an average expansion speed of c. So, in a universe with constant Hubble parameter, light emitted at the present time by objects outside the Hubble limit would never be seen by an observer on Earth.
That is, the Hubble limit would coincide with a cosmological event horizon (a boundary separating events visible at some time and those that are never visible[5]). See Hubble horizon for more details.
However, the Hubble parameter is not constant in various cosmological models[3] so that the Hubble limit does not, in general, coincide with a cosmological event horizon. For example, in a decelerating Friedmann universe the Hubble sphere expands with time, and its boundary overtakes light emitted by more distant galaxies so that light emitted at earlier times by objects outside the Hubble sphere still may eventually arrive inside the sphere and be seen by us.[3] Conversely, in an accelerating universe, the Hubble sphere shrinks with time, and its boundary overtakes light emitted by nearer galaxies so that light emitted at earlier times by objects inside the Hubble sphere will eventually recede outside the sphere and will never be seen by us.[1]
Observations indicate that the expansion of the universe is accelerating,[6] so that some objects that we can currently exchange signals with will one day cross our Hubble limit.
See also
{{Portal|Cosmology}}- Hubble's law
- Hubble horizon
- Particle horizon
References
2. ^{{cite journal |title=Study of the Quasi-isotropic Solution near the Cosmological Singularity in Presence of Bulk-Viscosity |author= N. Carlevaro & G. Montani |arxiv=0711.1952 |date=2009 |doi=10.1142/S0218271808012553 |volume=17 |issue= 6 |journal=International Journal of Modern Physics D |pages=881–896|bibcode = 2008IJMPD..17..881C }}
3. ^1 2 For a discussion of why objects that are outside the Earth's Hubble sphere can be seen from Earth, see {{cite journal |title=Expanding Confusion: common misconceptions of cosmological horizons and the superluminal expansion of the universe |author= TM Davis & CH Linewater |arxiv=astro-ph/0310808 |date=2003 |doi=10.1071/AS03040 |volume=21 |journal=Publications of the Astronomical Society of Australia |pages=97–109|bibcode = 2004PASA...21...97D }}
4. ^For an example of mistaken usage, see {{cite book |author=Max Tegmark |authorlink=Max Tegmark |chapter=Parallel Universes |title=Science and Ultimate Reality: From Quantum to Cosmos |editor-last=Barrow |editor-first=J. D. |editor2-last=Davies |editor2-first=J. D. |editor3-last=Harper |editor3-first=C. L. |pages=459ff |publisher=Cambridge University Press |date=2004 |isbn=978-0-521-83113-0 |chapter-url=https://books.google.com/?id=K_OfC0Pte_8C&pg=PA459}}
5. ^{{cite book |author=Edward Robert Harrison |page=439 |url=https://books.google.com/?id=-8PJbcA2lLoC&pg=PA439 |title=Masks of the Universe |isbn=978-0-521-66148-5 |publisher=Cambridge University Press |date=2000}}
6. ^{{cite journal |title = Cosmological Results from High-z Supernovae|date = 2003|arxiv = astro-ph/0305008|author = John L Tonry|journal = Astrophys J|volume = 594|issue = 1|bibcode = 2003ApJ...594....1T|doi = 10.1086/376865|display-authors = 1|last2 = Schmidt|first2 = Brian P.|last3 = Barris|first3 = Brian|last4 = Candia|first4 = Pablo|last5 = Challis|first5 = Peter|last6 = Clocchiatti|first6 = Alejandro|last7 = Coil|first7 = Alison L.|last8 = Filippenko|first8 = Alexei V.|last9 = Garnavich|first9 = Peter|pages = 1–24}}
External links
- The Hubble Volume Simulations
- Kerala Public Works Department
- Keralaputra
- Keralaputras
- Kerala Rapid Transit Corporation Ltd
- Kerala Rat
- Kerala Sahitya Akademi Award
- Kerala Sahitya Akademi Award for Biography and Autobiography
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- Kerala Sahitya Akademi Award for Poetry
- Kerala Sahitya Akademi Award for Scholarly Literature
- Kerala Sahitya Akademi Award for Story
- Kerala Sahitya Akademi Award for Translation
- Kerala Sahitya Akademi Award for Travelogue
- Kerala Samajam Model School
- Kerala Sampark Kranti
- Kerala Samyukta Socialist Party
- Kerala Sangeeta Nataka Akademi
- Kerala School of Mathematics
- Kerala Science and Technology Museum