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{{Short description|Topological structure used in a description of quantum gravity}} | |||
{{Beyond the Standard Model|cTopic=]}} | {{Beyond the Standard Model|cTopic=]}} | ||
In ], |
In ], the ] structure of '''spinfoam''' or '''spin foam'''<ref name="url Introduction to Loop Quantum Gravity and Spin Foams">{{cite arXiv |title= Introduction to Loop Quantum Gravity and Spin Foams |eprint=gr-qc/0409061 |last1=Perez |first1=Alejandro |year=2004 }}</ref> consists of two-dimensional faces representing a configuration required by ] to obtain a ] description of ]. These structures are employed in ] as a version of ]. | ||
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==In loop quantum gravity== | ||
{{main|Loop quantum gravity}} | |||
⚫ | |||
⚫ | A |
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⚫ | The ] of loop quantum gravity provides the best formulation of the dynamics of the theory of ] – a ] where the invariance under ] of ] applies. The resulting path integral represents a sum over all the possible configurations of spin foam.{{how|date=May 2016}} | ||
==The idea== | |||
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===Spin network=== | |||
⚫ | Spacetime |
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{{Main|Spin network}} | |||
⚫ | A spin network is a two-dimensional ], together with labels on its vertices and edges which encode aspects of a spatial geometry. | ||
⚫ | A spin network is defined as a diagram like the ] which makes a basis of ]s between the elements of a ] for the ]s defined over them, and for computations of amplitudes between two different ]s of the ]. Any evolution of the spin network provides a spin foam over a manifold of one dimension higher than the dimensions of the corresponding spin network.{{clarify|date=May 2016}} A spin foam is analogous to ].{{why|date=May 2016}} | ||
In Loop Quantum Gravity, the present Spinfoam Theory has been inspired by the work of ]-] model. The concept of a spin foam, although not called that at the time, was introduced in the paper "A Step Toward Pregeometry I: Ponzano-Regge Spin Networks and the Origin of Spacetime Structure in Four Dimensions" by Norman J. LaFave (gr-qc/9310036) (1993). In this paper, the concept of creating sandwiches of 4-geometry (and local time scale) from spin networks is described, along with the connection of these spin 4-geometry sandwiches to form paths of spin networks connecting given spin network boundaries (spin foams). Quantization of the structure leads to a generalized Feynman path integral over connected paths of spin networks between spin network boundaries. This paper goes beyond much of the later work by showing how 4-geometry is already present in the seemingly three dimensional spin networks, how local time scales occur, and how the field equations and conservation laws are generated by simple consistency requirements. The idea was reintroduced in <ref>{{cite arXiv|eprint=gr-qc/9612035|author1=Michael Reisenberger|author2=] |title='Sum over surfaces' form of loop quantum gravity.|class=gr-qc|year=1997}}</ref> and later developed into the ]. The formulation that is used nowadays is commonly called EPRL after the names of the authors of a series of seminal papers,<ref>{{cite arXiv|eprint=gr-qc/0711.0146|author1=Jonathan Engle|author2=Roberto Pereira|author3=]|author4=Etera Livine |title=LQG vertex with finite ]|class=gr-qc|year=2008}}</ref> but the theory has also seen fundamental contributions from the work of many others, such as ] (FK model) and ] (KKL model). | |||
===Spacetime=== | |||
Spin networks provide a language to describe the ] of space. Spin foam does the same job for spacetime. | |||
⚫ | Spacetime can be defined as a superposition of spin foams, which is a generalized Feynman diagram where instead of a graph, a higher-dimensional complex is used. In ] this sort of space is called a 2-]. A spin foam is a particular type of 2-], with labels for ], edges and ]. The boundary of a spin foam is a spin network, just as in the theory of manifolds, where the boundary of an n-manifold is an (n-1)-manifold. | ||
In loop quantum gravity, the present spin foam theory has been inspired by the work of ]. The idea was introduced by Reisenberger and Rovelli in 1997,<ref>{{cite journal |author1=Reisenberger |first=Michael |author2=Rovelli |first2=Carlo |author-link2=Carlo Rovelli |year=1997 |title="Sum over surfaces" form of loop quantum gravity |journal=Physical Review D |volume=56 |issue=6 |pages=3490–3508 |arxiv=gr-qc/9612035 |bibcode=1997PhRvD..56.3490R |doi=10.1103/PhysRevD.56.3490}}</ref> and later developed into the ]. The formulation that is used nowadays is commonly called EPRL after the names of the authors of a series of seminal papers,<ref>{{cite journal |author1=Engle |first=Jonathan |author2=Pereira |first2=Roberto |author3=Rovelli |first3=Carlo |author-link3=Carlo Rovelli |author4=Livine |first4=Etera |year=2008 |title=LQG vertex with finite Immirzi parameter |journal=Nuclear Physics B |volume=799 |issue=1–2 |pages=136–149 |arxiv=0711.0146 |bibcode=2008NuPhB.799..136E |doi=10.1016/j.nuclphysb.2008.02.018}}</ref> but the theory has also seen fundamental contributions from the work of many others, such as ] (FK model) and ] (KKL model). | |||
==Definition== | ==Definition== | ||
The partition function for a '''spin foam model''' is |
The summary partition function for a '''spin foam model''' is | ||
<math> Z:=\sum_{\Gamma}w(\Gamma)\left</math> | <math> Z:=\sum_{\Gamma}w(\Gamma)\left</math> | ||
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==See also== | ==See also== | ||
* ] | |||
* ] | * ] | ||
* ] | * ] | ||
* ] | * ] | ||
* ] | * ] | ||
* ] | |||
==References== | ==References== | ||
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== External links == | == External links == | ||
* {{cite journal |arxiv=gr-qc/9709052 |first=John C. |last=Baez |title=Spin foam models |journal=Classical and Quantum Gravity |year=1998 |volume=15 |issue=7 |pages=1827–1858 |doi=10.1088/0264-9381/15/7/004 |bibcode=1998CQGra..15.1827B |s2cid=6449360 }} | |||
* | |||
* {{cite journal |arxiv=gr-qc/0301113 |first=Alejandro |last=Perez |title=Spin Foam Models for Quantum Gravity |journal=Classical and Quantum Gravity |date=2003 |volume=20 |issue=6 |pages=R43–R104 |doi=10.1088/0264-9381/20/6/202 |s2cid=13891330 }} | |||
* | |||
⚫ | * {{cite arXiv |eprint=1102.3660 |first=Carlo |last=Rovelli |title=Zakopane lectures on loop gravity |date=2011 |class=gr-qc }} | ||
* | |||
⚫ | * |
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{{Quantum gravity}} | {{Quantum gravity}} |
Latest revision as of 18:18, 26 November 2024
Topological structure used in a description of quantum gravityIn physics, the topological structure of spinfoam or spin foam consists of two-dimensional faces representing a configuration required by functional integration to obtain a Feynman's path integral description of quantum gravity. These structures are employed in loop quantum gravity as a version of quantum foam.
In loop quantum gravity
Main article: Loop quantum gravityThe covariant formulation of loop quantum gravity provides the best formulation of the dynamics of the theory of quantum gravity – a quantum field theory where the invariance under diffeomorphisms of general relativity applies. The resulting path integral represents a sum over all the possible configurations of spin foam.
Spin network
Main article: Spin networkA spin network is a two-dimensional graph, together with labels on its vertices and edges which encode aspects of a spatial geometry.
A spin network is defined as a diagram like the Feynman diagram which makes a basis of connections between the elements of a differentiable manifold for the Hilbert spaces defined over them, and for computations of amplitudes between two different hypersurfaces of the manifold. Any evolution of the spin network provides a spin foam over a manifold of one dimension higher than the dimensions of the corresponding spin network. A spin foam is analogous to quantum history.
Spacetime
Spin networks provide a language to describe the quantum geometry of space. Spin foam does the same job for spacetime.
Spacetime can be defined as a superposition of spin foams, which is a generalized Feynman diagram where instead of a graph, a higher-dimensional complex is used. In topology this sort of space is called a 2-complex. A spin foam is a particular type of 2-complex, with labels for vertices, edges and faces. The boundary of a spin foam is a spin network, just as in the theory of manifolds, where the boundary of an n-manifold is an (n-1)-manifold.
In loop quantum gravity, the present spin foam theory has been inspired by the work of Ponzano–Regge model. The idea was introduced by Reisenberger and Rovelli in 1997, and later developed into the Barrett–Crane model. The formulation that is used nowadays is commonly called EPRL after the names of the authors of a series of seminal papers, but the theory has also seen fundamental contributions from the work of many others, such as Laurent Freidel (FK model) and Jerzy Lewandowski (KKL model).
Definition
The summary partition function for a spin foam model is
with:
- a set of 2-complexes each consisting out of faces , edges and vertices . Associated to each 2-complex is a weight
- a set of irreducible representations which label the faces and intertwiners which label the edges.
- a vertex amplitude and an edge amplitude
- a face amplitude , for which we almost always have
See also
- Group field theory
- Loop quantum gravity
- Lorentz invariance in loop quantum gravity
- String-net liquid
References
- Perez, Alejandro (2004). " Introduction to Loop Quantum Gravity and Spin Foams". arXiv:gr-qc/0409061.
- Reisenberger, Michael; Rovelli, Carlo (1997). ""Sum over surfaces" form of loop quantum gravity". Physical Review D. 56 (6): 3490–3508. arXiv:gr-qc/9612035. Bibcode:1997PhRvD..56.3490R. doi:10.1103/PhysRevD.56.3490.
- Engle, Jonathan; Pereira, Roberto; Rovelli, Carlo; Livine, Etera (2008). "LQG vertex with finite Immirzi parameter". Nuclear Physics B. 799 (1–2): 136–149. arXiv:0711.0146. Bibcode:2008NuPhB.799..136E. doi:10.1016/j.nuclphysb.2008.02.018.
External links
- Baez, John C. (1998). "Spin foam models". Classical and Quantum Gravity. 15 (7): 1827–1858. arXiv:gr-qc/9709052. Bibcode:1998CQGra..15.1827B. doi:10.1088/0264-9381/15/7/004. S2CID 6449360.
- Perez, Alejandro (2003). "Spin Foam Models for Quantum Gravity". Classical and Quantum Gravity. 20 (6): R43–R104. arXiv:gr-qc/0301113. doi:10.1088/0264-9381/20/6/202. S2CID 13891330.
- Rovelli, Carlo (2011). "Zakopane lectures on loop gravity". arXiv:1102.3660 .
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