Geodesic
Classical 6j-symbols and the tetrahedron
Roberts, Justin1
1 Department of Mathematics and Statistics, Edinburgh University, EH3 9JZ, Scotland
Geometry & topology, Tome 3 (1999) no. 1, pp. 21-66.

Voir la notice de l'article provenant de la source Mathematical Sciences Publishers

A classical 6j–symbol is a real number which can be associated to a labelling of the six edges of a tetrahedron by irreducible representations of SU(2). This abstract association is traditionally used simply to express the symmetry of the 6j–symbol, which is a purely algebraic object; however, it has a deeper geometric significance. Ponzano and Regge, expanding on work of Wigner, gave a striking (but unproved) asymptotic formula relating the value of the 6j–symbol, when the dimensions of the representations are large, to the volume of an honest Euclidean tetrahedron whose edge lengths are these dimensions. The goal of this paper is to prove and explain this formula by using geometric quantization. A surprising spin-off is that a generic Euclidean tetrahedron gives rise to a family of twelve scissors-congruent but non-congruent tetrahedra.

DOI : 10.2140/gt.1999.3.21
Keywords: $6j$–symbol, asymptotics, tetrahedron, Ponzano–Regge formula, geometric quantization, scissors congruence

Roberts, Justin 1

1 Department of Mathematics and Statistics, Edinburgh University, EH3 9JZ, Scotland 
@article{GT_1999_3_1_a1,
     author = {Roberts, Justin},
     title = {Classical 6j-symbols and the tetrahedron},
     journal = {Geometry & topology},
     pages = {21--66},
     publisher = {mathdoc},
     volume = {3},
     number = {1},
     year = {1999},
     doi = {10.2140/gt.1999.3.21},
     url = {http://geodesic.mathdoc.fr/articles/10.2140/gt.1999.3.21/}
}
TY  - JOUR
AU  - Roberts, Justin
TI  - Classical 6j-symbols and the tetrahedron
JO  - Geometry & topology
PY  - 1999
SP  - 21
EP  - 66
VL  - 3
IS  - 1
PB  - mathdoc
UR  - http://geodesic.mathdoc.fr/articles/10.2140/gt.1999.3.21/
DO  - 10.2140/gt.1999.3.21
ID  - GT_1999_3_1_a1
ER  - 
%0 Journal Article
%A Roberts, Justin
%T Classical 6j-symbols and the tetrahedron
%J Geometry & topology
%D 1999
%P 21-66
%V 3
%N 1
%I mathdoc
%U http://geodesic.mathdoc.fr/articles/10.2140/gt.1999.3.21/
%R 10.2140/gt.1999.3.21
%F GT_1999_3_1_a1
Roberts, Justin. Classical 6j-symbols and the tetrahedron. Geometry & topology, Tome 3 (1999) no. 1, pp. 21-66. doi : 10.2140/gt.1999.3.21. http://geodesic.mathdoc.fr/articles/10.2140/gt.1999.3.21/

[1] R Carter, G Segal, I Macdonald, Lectures on Lie groups and Lie algebras, London Mathematical Society Student Texts 32, Cambridge University Press (1995)

[2] P Cartier, Décomposition des polyèdres: le point sur le troisième problème de Hilbert, Astérisque (1986) 261

[3] W Fulton, J Harris, Representation theory, Graduate Texts in Mathematics 129, Springer (1991)

[4] V Guillemin, S Sternberg, Geometric quantization and multiplicities of group representations, Invent. Math. 67 (1982) 515

[5] N Hitchin, Metrics on moduli spaces, from: "The Lefschetz centennial conference, Part I (Mexico City, 1984)", Contemp. Math. 58, Amer. Math. Soc. (1986) 157

[6] L H Kauffman, S L Lins, Temperley-Lieb recoupling theory and invariants of 3–manifolds, Annals of Mathematics Studies 134, Princeton University Press (1994)

[7] A A Kirillov, Geometric quantization, from: "Dynamical systems IV", Encyclopaedia Math. Sci. 4, Springer (2001) 139

[8] D A Klain, G C Rota, Introduction to geometric probability, Lezioni Lincee, Cambridge University Press (1997)

[9] D Mcduff, D Salamon, Introduction to symplectic topology, Oxford Mathematical Monographs, The Clarendon Press Oxford University Press (1995)

[10] J Milnor, Euler characteristic and finitely additive Steiner measures, from: "Collected papers vol. 1", Publish or Perish (1994)

[11] J Milnor, The Schläfli differential equality, from: "Collected papers vol. 1", Publish or Perish (1994)

[12] D Mumford, Geometric invariant theory, Ergebnisse der Mathematik und ihrer Grenzgebiete 34, Springer (1965)

[13] W D Neumann, Hilbert's 3rd problem and invariants of 3–manifolds, from: "The Epstein birthday schrift", Geom. Topol. Monogr. 1, Geom. Topol. Publ., Coventry (1998) 383

[14] G Ponzano, T Regge, Semi-classical limit of Racah coefficients, from: "Spectroscopic and group theoretical methods in physics" (editor F Bloch), North-Holland (1968)

[15] D A Varshalovich, A N Moskalev, V K Khersonskiĭ, Quantum theory of angular momentum: irreducible tensors, spherical harmonics, vector coupling coefficients, $3nj$ symbols, World Scientific (1988)

[16] N J Vilenkin, A U Klimyk, Representation of Lie groups and special functions Vol. 1, Mathematics and its Applications (Soviet Series) 72, Kluwer Academic Publishers Group (1991)

[17] E P Wigner, Group theory: And its application to the quantum mechanics of atomic spectra, Pure and Applied Physics 5, Academic Press (1959)

Cité par Sources :