Planck length: Difference between revisions

Browse history interactively ← Previous edit Next edit →Content deleted Content addedVisual WikitextInline

Revision as of 21:39, 25 October 2013 editAnomieBOT (talk \| contribs)Bots6,589,606 editsm Dating maintenance tags: {{Cn}}← Previous edit		Revision as of 08:48, 27 October 2013 edit undo14.198.220.253 (talk) →Theoretical significance: Everyone knows which "Planck length" we refers to, too many "the" in this section, bad English.Next edit →
Line 17:		Line 17:

	==Theoretical significance==		==Theoretical significance==
	There is currently no proven physical significance of the Planck length; it is, however, a topic of theoretical research. Since ~~the~~ Planck length is so many orders of magnitude smaller than any current instrument could possibly measure, there is no way of examining it directly. According to the ], ~~the~~ Planck length is, in principle, within a factor of order unity, the shortest measurable length – and no improvement in measurement instruments could change that.		There is currently no proven physical significance of the Planck length; it is, however, a topic of theoretical research. Since Planck length is so many orders of magnitude smaller than any current instrument could possibly measure, there is no way of examining it directly. According to the ], Planck length is, in principle, within a factor of order unity, the shortest measurable length – and no improvement in measurement instruments could change that.

	In some forms of ], ~~the~~ Planck length is the length scale at which the structure of spacetime becomes dominated by quantum effects, and it is impossible to determine the difference between two locations less than one Planck length apart. The precise effects of quantum gravity are unknown; ~~often~~ it is ~~suggested~~ that spacetime might have a discrete or ] structure at a Planck length scale.{{cn\|date=October 2013}}		In some forms of ], Planck length is the length scale at which the structure of spacetime becomes dominated by quantum effects, and it is impossible to determine the difference between two locations less than one Planck length apart. The precise effects of quantum gravity are unknown; it is often guessed that spacetime might have a discrete or ] structure at a Planck length scale.{{cn\|date=October 2013}}

	The Planck area, equal to the square of ~~the~~ Planck length, plays a role in ]. The value of this entropy, in units of the ], is known to be given by <math>A/4\ell_\text{P}^2</math>, where <math>A</math> is the area of the ]. ~~The~~ Planck area is the area by which a spherical ] increases when the black hole swallows one bit of information, as was proven by ].<ref>{{cite web\|url=http://prd.aps.org/abstract/PRD/v7/i8/p2333_1 \|title=Phys. Rev. D 7, 2333 (1973): Black Holes and Entropy \|publisher=Prd.aps.org \|date= \|accessdate=2013-10-21}}</ref>		The Planck area, equal to the square of Planck length, plays a role in ]. The value of this entropy, in units of the ], is known to be given by <math>A/4\ell_\text{P}^2</math>, where <math>A</math> is the area of the ]. Planck area is the area by which a spherical ] increases when the black hole swallows one bit of information, as was proven by ].<ref>{{cite web\|url=http://prd.aps.org/abstract/PRD/v7/i8/p2333_1 \|title=Phys. Rev. D 7, 2333 (1973): Black Holes and Entropy \|publisher=Prd.aps.org \|date= \|accessdate=2013-10-21}}</ref>

	If ]s exist, the measured strength of gravity may be much smaller than its true (small-scale) value. In this case the Planck length would have no fundamental physical significance, and quantum gravitational effects would appear at other scales.		If ]s exist, the measured strength of gravity may be much smaller than its true (small-scale) value. In this case the Planck length would have no fundamental physical significance, and quantum gravitational effects would appear at other scales.

Revision as of 08:48, 27 October 2013

This article needs additional citations for verification. Please help improve this article by adding citations to reliable sources. Unsourced material may be challenged and removed.
Find sources: "Planck length" – news · newspapers · books · scholar · JSTOR (January 2008) (Learn how and when to remove this message)

Template:Unit of length In physics, the Planck length, denoted ℓ_P, is a unit of length, equal to 1.616199(97)×10 metres. It is a base unit in the system of Planck units, developed by physicist Max Planck. The Planck length can be defined from three fundamental physical constants: the speed of light in a vacuum, Planck's constant, and the gravitational constant.

Value

The Planck length $\ell _{\text{P}}$ is defined as

\ell _{\text{P}}={\sqrt {\frac {\hbar G}{c^{3}}}}\approx 1.616\;199(97)\times 10^{-35}{\mbox{ m}}

where $c$ is the speed of light in a vacuum, $G$ is the gravitational constant, and $\hbar$ is the reduced Planck constant. The two digits enclosed by parentheses are the estimated standard error associated with the reported numerical value.

The Planck length is about 10 times the diameter of a proton, and thus is exceedingly small. It is considered the smallest possible length.

Theoretical significance

There is currently no proven physical significance of the Planck length; it is, however, a topic of theoretical research. Since Planck length is so many orders of magnitude smaller than any current instrument could possibly measure, there is no way of examining it directly. According to the generalized uncertainty principle, Planck length is, in principle, within a factor of order unity, the shortest measurable length – and no improvement in measurement instruments could change that.

In some forms of quantum gravity, Planck length is the length scale at which the structure of spacetime becomes dominated by quantum effects, and it is impossible to determine the difference between two locations less than one Planck length apart. The precise effects of quantum gravity are unknown; it is often guessed that spacetime might have a discrete or foamy structure at a Planck length scale.

The Planck area, equal to the square of Planck length, plays a role in black hole entropy. The value of this entropy, in units of the Boltzmann constant, is known to be given by $A/4\ell _{\text{P}}^{2}$ , where $A$ is the area of the event horizon. Planck area is the area by which a spherical black hole increases when the black hole swallows one bit of information, as was proven by Jacob Bekenstein.

If large extra dimensions exist, the measured strength of gravity may be much smaller than its true (small-scale) value. In this case the Planck length would have no fundamental physical significance, and quantum gravitational effects would appear at other scales.

In string theory, the Planck length is the order of magnitude of the oscillating strings that form elementary particles, and shorter lengths do not make physical sense.

In loop quantum gravity, area is quantized, and the Planck area is, within a factor of order unity, the smallest possible area value.

In doubly special relativity, the Planck length is observer-invariant.

The search for the laws of physics valid at the Planck length is a part of the search for the theory of everything.

Visualization

The size of the Planck length can be visualized as follows: if a particle or dot about 0.1mm in size (which is at or near the smallest the unaided human eye can see) were magnified in size to be as large as the observable universe, then inside that universe-sized "dot", the Planck length would be roughly the size of an actual 0.1mm dot, that is, about the size of smallest object the naked human eye can see. In other words, the diameter of the observable universe is to within less than an order of magnitude, larger than a 0.1 millimeter object, roughly at or near the limits of the unaided human eye, by about the same factor (10^31) as that 0.1mm object or dot is larger than the Planck length. More simply - on a logarithmic scale, a dot is halfway between the Planck length and the size of the universe.

Notes and references

John Baez, The Planck Length
NIST, "Planck length", NIST's published CODATA constants
"Phys. Rev. D 7, 2333 (1973): Black Holes and Entropy". Prd.aps.org. Retrieved 2013-10-21.
Cliff Burgess (November 2007). "The Great Cosmic Roller-Coaster Ride". Scientific American. Scientific American, Inc. p. 55. {{cite news}}: |format= requires |url= (help); Unknown parameter |coauthors= ignored (|author= suggested) (help)

Bibliography

Garay, Luis J. (1995). "Quantum gravity and minimum length". International Journal of Modern Physics A. 10 (2): 145 ff. arXiv:arXiv:gr-qc/9403008v2. Bibcode:1995IJMPA..10..145G. doi:10.1142/S0217751X95000085. {{cite journal}}: Check |arxiv= value (help); Unknown parameter |month= ignored (help)

External links

Bowley, Roger (2010). "Planck Length". Sixty Symbols. Brady Haran for the University of Nottingham. {{cite web}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)

Template:Planck's natural units

Portal:

Physics

Categories:

Misplaced Pages