In physics, the topological structure of spinfoam or spin foam[1] 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

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The 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.[how?]

Spin network

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A 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.[clarification needed] A spin foam is analogous to quantum history.[why?]

Spacetime

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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,[2] 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,[3] 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

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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

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References

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  1. ^ Perez, Alejandro (2004). "[gr-qc/0409061] Introduction to Loop Quantum Gravity and Spin Foams". arXiv:gr-qc/0409061.
  2. ^ 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.
  3. ^ 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.
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