Tomita–Takesaki theory

In the theory of von Neumann algebras, a part of the mathematical field of functional analysis, Tomita–Takesaki theory is a method for constructing modular automorphisms of von Neumann algebras from the polar decomposition of a certain involution. It is essential for the theory of type III factors, and has led to a good structure theory for these previously intractable objects.

The theory was first found by Minoru Tomita (1967) in about 1957–1967, but his work was hard to follow and mostly unpublished, and little notice was taken of it until Masamichi Takesaki (1970) wrote an account of Tomita's theory.

Modular automorphisms of a state

Suppose that M is a von Neumann algebra acting on a Hilbert space H, and Ω is a separating and cyclic vector of H of norm 1. (Cyclic means that MΩ is dense in H, and separating means that the map from M to MΩ is injective.) We write φ for the state φ(x)=(xΩ,Ω) of M, so that H is constructed from φ using the GNS construction. We can define an unbounded antilinear operator S₀ on H with domain MΩ by setting

S₀(mΩ)= m^*Ω

for all m in M, and similarly we can define an unbounded antilinear operator F₀ on H with domain M'Ω by setting

F₀(mΩ)= m^*Ω

for m in M′. These operators are closable, and we denote their closures by S and F = S*. They have polar decompositions

S = J|S| = JΔ^1/2 = Δ^−1/2J

F = J|F| = JΔ^−1/2 = Δ^1/2J

where J = J⁻¹ = J* is an antilinear isometry called the modular conjugation and Δ = S^*S= FS is a positive self adjoint operator called the modular operator.

The main result of Tomita–Takesaki theory states that:

JMJ = M′, the commutant of M.

There is a 1-parameter family of modular automorphisms σ^φ_t of M associated to the state φ, defined by

σ^φ_t(x) = Δ^itxΔ^−it

The Connes cocycle

The modular automorphism group of a von Neumann algebra M depends on the choice of state φ. Connes discovered that changing the state does not change the image of the modular automorphism in the outer automorphism group of M. More precisely, given two faithful states φ and ψ of M, we can find unitary elements u_t of M for all real t such that

σ^ψ_t(x) = u_tσ^φ_t(x)u_t⁻¹

so that the modular automorphisms differ by inner automorphisms, and moreover u_t satisfies the 1-cocycle condition

u_s+t = u_sσ^φ_s(u_t)

In particular, there is a canonical homomorphism from the additive group of reals to the outer automorphism group of M, that is independent of the choice of faithful state.

KMS states

The term KMS state comes from the Kubo–Martin–Schwinger condition in quantum statistical mechanics.

A KMS state φ on a von Neumann algebra M with a given 1-parameter group of automorphisms α_t is a state fixed by the automorphisms such that for every pair of elements A, B of M there is a bounded continuous function F in the strip 0≤Im(t)≤1, holomorphic in the interior, such that

F(t) = φ(Aα_t(B))

F(t+i) = φ(α_t(B)A),

Tasaki and Winnink showed that a (faithful semi finite normal) state φ is a KMS state for the 1-parameter group of modular automorphisms σ^φ_−t. Moreover this characterizes the modular automorphisms of φ.

(There is often an extra parameter, denoted by β, used in the theory of KMS states. In the description above this has been normalized to be 1 by rescaling the 1-parameter family of automorphisms.)

Structure of type III factors

We have seen above that there is a canonical homomorphism δ from the group of reals to the outer automorphism group of a von Neumann algebra, given by modular automorphisms. The kernel of δ is an important invariant of the algebra. For simplicity assume that the von Neumann algebra is a factor. Then the possibilities for the kernel of δ are:

• The whole real line. In this case δ is trivial and the factor is type I or II.
• A proper dense subgroup of the real line. Then the factor is called a factor of type III₀.
• A discrete subgroup generated by some x > 0. Then the factor is called a factor of type III_λ with 0 < λ = exp(−2π/x) < 1, or sometimes a Powers factor.
• The trivial group 0. Then the factor is called a factor of type III₁. (This is in some sense the generic case.)

Hilbert algebras

The main results of Tomita–Takesaki theory were proved using left and right Hilbert algebras.

A left Hilbert algebra is an algebra with involution x→x^♯ and an inner product (,) such that

1. Left multiplication by a fixed a ∈ A is a bounded operator.
2. ♯ is the adjoint; in other words (xy,z) = (y, x^♯z).
3. The involution ^♯ is preclosed
4. The subalgebra spanned by all products xy is dense in A.

A right Hilbert algebra is defined similarly (with an involution ♭) with left and right reversed in the conditions above.

A Hilbert algebra is a left Hilbert algebra such that in addition ♯ is an isometry, in other words (x,y) = (y^♯, x^♯).

Examples: If M is a von Neumann algebra acting on a Hilbert space H with a cyclic separating vector v, then put A = Mv and define (xv)(yv) = xyv and (xv)^♯ = x*v. Tomita's key discovery was that this makes A into a left Hilbert algebra, so in particular the closure of the operator ^♯ has a polar decomposition as above. The vector v is the identity of A, so A is a unital left Hilbert algebra.

If G is a locally compact group, then the vector space of all continuous complex functions on G with compact support is a right Hilbert algebra if multiplication is given by convolution, and x^♭(g) = x(g⁻¹)*.

References

• Borchers, H. J. (2000), "On revolutionizing quantum field theory with Tomita's modular theory", Journal of Mathematical Physics 41 (6): 3604–3673, doi:10.1063/1.533323, MR1768633 
  • Longer version with proofs
• Bratteli, O.; Robinson, D.W. (1987), Operator Algebras and Quantum Statistical Mechanics 1, Second Edition, Springer-Verlag, ISBN 3-540-17093-6 
• Connes, Alain (1994), Non-commutative geometry, Boston, MA: Academic Press, ISBN 978-0-12-185860-5, ftp://ftp.alainconnes.org/book94bigpdf.pdf 
• Dixmier, Jacques (1981), von Neumann algebras, North-Holland Mathematical Library, 27, Amsterdam: North-Holland, ISBN 978-0-444-86308-9, MR641217 
• Inoue, A. (2001), "Tomita–Takesaki theory", in Hazewinkel, Michiel, Encyclopaedia of Mathematics, Springer, ISBN 978-1556080104, http://eom.springer.de/T/t120150.htm 
• Nakano, Hidegorô (1950), "Hilbert algebras", The Tohoku Mathematical Journal. Second Series 2: 4–23, doi:10.2748/tmj/1178245666, MR0041362 
• Shtern, A.I. (2001), "Hilbert algebra", in Hazewinkel, Michiel, Encyclopaedia of Mathematics, Springer, ISBN 978-1556080104, http://eom.springer.de/H/h047230.htm 
• Summers, S. J. (2006), "Tomita–Takesaki Modular Theory", in Françoise, Jean-Pierre; Naber, Gregory L.; Tsun, Tsou Sheung, Encyclopedia of mathematical physics, Academic Press/Elsevier Science, Oxford, arXiv:math-ph/0511034, ISBN 978-0-12-512660-1, MR2238867 
• Takesaki, M. (1970), Tomita's theory of modular Hilbert algebras and its applications, Lecture Notes Math., 128, Springer, doi:10.1007/BFb0065832, ISBN 978-3-540-04917-3 
• Takesaki, Masamichi (2003), Theory of operator algebras. II, Encyclopaedia of Mathematical Sciences, 125, Berlin, New York: Springer-Verlag, ISBN 978-3-540-42914-2, MR1943006 
• Tomita, Minoru (1967), "On canonical forms of von Neumann algebras" (in Japanese), Fifth Functional Analysis Sympos. (Tôhoku Univ., Sendai, 1967), Tôhoku Univ., Sendai: Math. Inst., pp. 101–102, MR0284822 
• Tomita, M., Quasi-standard von Neumann algebras, unpublished