KMS state

Kubo-Martin-Schwinger condition as featured on a monument in front of Warsaw University's Centre of New Technologies

In the statistical mechanics of quantum mechanical systems and quantum field theory, the properties of a system in thermal equilibrium can be described by a mathematical object called a Kubo-Martin-Schwinger state or, more commonly, a KMS state: a state satisfying the KMS condition. Kubo (1957) introduced the condition, Martin & Schwinger (1959) used it to define thermodynamic Greens functions, and Rudolf Haag, M. Winnink, and N. M. Hugenholtz (1967) used the condition to define equilibrium states and called it the KMS condition.

Preliminaries

The simplest case to study is that of a finite-dimensional Hilbert space, in which one does not encounter complications like phase transitions or spontaneous symmetry breaking. The density matrix of a thermal state is given by

\rho_{\beta,\mu}=\frac{e^{-\beta \left(H-\mu N\right)}}{\mathrm{Tr}\left[ e^{-\beta \left(H-\mu N\right)} \right]}=\frac{e^{-\beta \left(H-\mu N\right)}}{Z(\beta,\mu)}

where H is the Hamiltonian operator and N is the particle number operator (or charge operator, if we wish to be more general) and

Z(\beta,\mu)\ \stackrel{\mathrm{def}}{=}\  \mathrm{Tr}\left[ e^{-\beta \left(H-\mu N\right)} \right]

is the partition function. We assume that N commutes with H, or in other words, that particle number is conserved.

In the Heisenberg picture, the density matrix does not change with time, but the operators are time-dependent. In particular, translating an operator A by τ into the future gives the operator

\alpha_\tau(A)\ \stackrel{\mathrm{def}}{=}\  e^{iH\tau}A e^{-iH\tau}.

A combination of time translation with an internal symmetry "rotation" gives the more general

\alpha^{\mu}_{\tau}(A)\ \stackrel{\mathrm{def}}{=}\  e^{i\left(H-\mu N\right)\tau} A e^{-i\left(H-\mu N\right)\tau}

A bit of algebraic manipulation shows that the expected values

\langle\alpha^\mu_\tau(A)B\rangle_{\beta,\mu}=\mathrm{Tr}\left[\rho \alpha^\mu_\tau(A)B\right]=\mathrm{Tr}\left[\rho B \alpha^\mu_{\tau+i\beta}(A)\right]=\langle B\alpha^\mu_{\tau+i\beta}(A)\rangle_{\beta,\mu}

for any two operators A and B and any real τ (we are working with finite-dimensional Hilbert spaces after all). We used the fact that the density matrix commutes with any function of (HN) and that the trace is cyclic.

As hinted at earlier, with infinite dimensional Hilbert spaces, we run into a lot of problems like phase transitions, spontaneous symmetry breaking, operators that are not trace class, divergent partition functions, etc..

The complex functions of z, \langle\alpha^\mu_z(A)B\rangle converges in the complex strip -\beta < \Im{z} < 0 whereas \langle B\alpha^\mu_z(A)\rangle converges in the complex strip 0 < \Im{z} < \beta if we make certain technical assumptions like the spectrum of HN is bounded from below and its density does not increase exponentially (see Hagedorn temperature). If the functions converge, then they have to be analytic within the strip they are defined over as their derivatives,

\frac{d}{dz}\langle\alpha^\mu_z(A)B\rangle=i\langle\alpha^\mu_z\left(\left[H-\mu N,A\right]\right)B\rangle

and

\frac{d}{dz}\langle B\alpha^\mu_z(A)\rangle = i\langle B\alpha^\mu_z\left(\left[H-\mu N,A\right]\right)\rangle

exist.

However, we can still define a KMS state as any state satisfying

\langle \alpha^\mu_\tau(A)B\rangle=\langle B\alpha^\mu_{\tau+i\beta}(A)\rangle

with \langle\alpha^\mu_z(A)B\rangle and \langle B\alpha^\mu_z(A)\rangle being analytic functions of z within their domain strips.

\langle\alpha^\mu_\tau(A)B\rangle and \langle B\alpha^\mu_{\tau+i\beta}(A)\rangle are the boundary distribution values of the analytic functions in question.

This gives the right large volume, large particle number thermodynamic limit. If there is a phase transition or spontaneous symmetry breaking, the KMS state is not unique.

The density matrix of a KMS state is related to unitary transformations involving time translations (or time translations and an internal symmetry transformation for nonzero chemical potentials) via the Tomita–Takesaki theory.

References

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