Diagonal form

In mathematics, the fuzzy sphere is one of the simplest and most canonical examples of non-commutative geometry. Ordinarily, the functions defined on a sphere form a commuting algebra. A fuzzy sphere differs from an ordinary sphere because the algebra of functions on it is not commutative. It is generated by spherical harmonics whose spin l is at most equal to some j. The terms in the product of two spherical harmonics that involve spherical harmonics with spin exceeding j are simply omitted in the product. This truncation replaces an infinite-dimensional commutative algebra by a ${\displaystyle j^2}$-dimensional non-commutative algebra.

The simplest way to see this sphere is to realize this truncated algebra of functions as a matrix algebra on some finite dimensional vector space. Take the three j-dimensional matrices ${\displaystyle J_a,a=1,2,3}$ that form a basis for the j dimensional irreducible representation of the Lie algebra SU(2). They satisfy the relations ${\displaystyle [J_a,J_b]=i{ϵ}_{abc}{J}_c}$, where ${\displaystyle {ϵ}_{abc}}$ is the totally antisymmetric symbol with ${\displaystyle {ϵ}_{123}=1}$, and generate via the matrix product the algebra ${\displaystyle M_j}$ of j dimensional matrices. The value of the SU(2) Casimir operator in this representation is

${\displaystyle J_1^2+J_2^2+J_3^2=\frac{1}{4}(j^2-1)I}$

where I is the j-dimensional identity matrix. Thus, if we define the 'coordinates' ${\displaystyle x_a=k{r}^{-1}{J}_a}$ where r is the radius of the sphere and k is a parameter, related to r and j by ${\displaystyle 4r^4=k^2(j^2-1)}$, then the above equation concerning the Casimir operator can be rewritten as

${\displaystyle x_1^2+x_2^2+x_3^2=r^2}$,

which is the usual relation for the coordinates on a sphere of radius r embedded in three dimensional space.

One can define an integral on this space, by

${\displaystyle \underset{S^2}{\int }fd\mathrm{\Omega }:=2\pi k\text{Tr}(F)}$

where F is the matrix corresponding to the function f. For example, the integral of unity, which gives the surface of the sphere in the commutative case is here equal to

${\displaystyle 2\pi k\text{Tr}(I)=2\pi kj=4\pi r^2\frac{j}{\sqrt{j^2-1}}}$

which converges to the value of the surface of the sphere if one takes j to infinity.

See also

• Fuzzy torus

Notes

• Jens Hoppe, "Membranes and Matrix Models", lectures presented during the summer school on ‘Quantum Field Theory – from a Hamiltonian Point of View’, August 2–9, 2000, arXiv:hep-th/0206192
• John Madore, An introduction to Noncommutative Differential Geometry and its Physical Applications, London Mathematical Society Lecture Note Series. 257, Cambridge University Press 2002

References

J. Hoppe, Quantum Theory of a Massless Relativistic Surface and a Two dimensional Bound State Problem. PhD thesis, Massachusetts Institute of Technology, 1982.