Action-angle coordinates

In quantum mechanics, in particular quantum information, the Range criterion is a necessary condition that a state must satisfy in order to be separable. In other words, it is a separability criterion.

The result

Consider a quantum mechanical system composed of n subsystems. The state space H of such a system is the tensor product of those of the subsystems, i.e. ${\displaystyle H=H_1\otimes \cdots \otimes H_n}$.

For simplicity we will assume throughout that all relevant state spaces are finite dimensional.

The criterion reads as follows: If ρ is a separable mixed state acting on H, then the range of ρ is spanned by a set of product vectors.

Proof

In general, if a matrix M is of the form ${\displaystyle M=\sum _i{v}_i{v}_i^{*}}$, it is obvious that the range of M, Ran(M), is contained in the linear span of ${\displaystyle \{v_i\}}$. On the other hand, we can also show ${\displaystyle v_i}$ lies in Ran(M), for all i. Assume without loss of generality i = 1. We can write ${\displaystyle M=v_1{v}_1^{*}+T}$, where T is Hermitian and positive semidefinite. There are two possibilities:

1) span${\displaystyle \{v_1\}\subset }$Ker(T). Clearly, in this case, ${\displaystyle v_1\in }$ Ran(M).

2) Notice 1) is true if and only if Ker(T)${\displaystyle {}^{\perp }\subset }$ span${\displaystyle \{v_1{\}}^{\perp }}$, where ${\displaystyle \perp }$ denotes orthogonal compliment. By Hermiticity of T, this is the same as Ran(T)${\displaystyle \subset }$ span${\displaystyle \{v_1{\}}^{\perp }}$. So if 1) does not hold, the intersection Ran(T) ${\displaystyle \cap }$ span${\displaystyle \{v_1\}}$ is nonempty, i.e. there exists some complex number α such that ${\displaystyle Tw=\alpha v_1}$. So

${\displaystyle Mw=⟨w,v_1⟩v_1+Tw=(⟨w,v_1⟩+\alpha )v_1.}$

Therefore ${\displaystyle v_1}$ lies in Ran(M).

Thus Ran(M) coincides with the linear span of ${\displaystyle \{v_i\}}$. The range criterion is a special case of this fact.

A density matrix ρ acting on H is separable if and only if it can be written as

${\displaystyle \rho =\sum _i{\psi }_{1,i}{\psi }_{1,i}^{*}\otimes \cdots \otimes {\psi }_{n,i}{\psi }_{n,i}^{*}}$

where ${\displaystyle {\psi }_{j,i}{\psi }_{j,i}^{*}}$ is a (un-normalized) pure state on the j-th subsystem. This is also

${\displaystyle \rho =\sum _i({\psi }_{1,i}\otimes \cdots \otimes {\psi }_{n,i})({\psi }_{1,i}^{*}\otimes \cdots \otimes {\psi }_{n,i}^{*}).}$

But this is exactly the same form as M from above, with the vectorial product state ${\displaystyle {\psi }_{1,i}\otimes \cdots \otimes {\psi }_{n,i}}$ replacing ${\displaystyle v_i}$. It then immediately follows that the range of ρ is the linear span of these product states. This proves the criterion.

References

• P. Horodecki, "Separability Criterion and Inseparable Mixed States with Positive Partial Transposition", Physics Letters A 232, (1997).