LOCC, or local operations and classical communication, is a method in quantum information theory where a local (product) operation is performed on part of the system, and where the result of that operation is "communicated" classically to another part where usually another local operation is performed conditioned on the information received.
The formal definition of the set of LOCC operations is complicated due to the fact that later local operations depend in general on all the previous classical communication and due to the unbounded number of communication rounds. For any finite number
r\geq1
\operatorname{LOCC}r
r
r
A one-round LOCC
\operatorname{LOCC}1
\left\{l{E}x\right\}
l{E}x
x
l{E}x=otimesj({\cal
| j) | |
| E} | |
| x |
j=K
K
| K | |
| l{E} | |
| x |
l{E}x=otimesj\not=K({\cal
| x}) ⊗ {\cal | |
| T | |
| j |
E}K
K
| K\right\} | |
| \left\{l{E} | |
| x |
x
x
{\cal
| j | |
| T} | |
| x |
Then
\operatorname{LOCC}r
\operatorname{LOCC}r-1
\operatorname{LOCC}1
The union of all
\operatorname{LOCC}r
\operatorname{LOCC}N
\overline{\operatorname{LOCC}}N
It can be shown that all these sets are different:[1]
\operatorname{LOCC}r\subset\operatorname{LOCC}r+1\subset\operatorname{LOCC}N\subset\overline{\operatorname{LOCC}}N
The set of all LOCC operations is contained in the set
\operatorname{SEP}
\operatorname{SEP}
{\calE}(\rho)=\suml
| l | |
| K | |
| 1 ⊗ |
| l | |
| K | |
| 2... ⊗ |
KN\rho
| l | |
| (K | |
| 1 ⊗ |
| l | |
| K | |
| 2... ⊗ |
| \dagger, | |
| K | |
| N) |
\suml
| l | |
| K | |
| 1 ⊗ |
| l | |
| K | |
| 2... ⊗ |
| l | |
| K | |
| 1 ⊗ |
| l | |
| K | |
| 2... ⊗ |
| \dagger=1 | |
| K | |
| N) |
\operatorname{SEP}
\overline{\operatorname{LOCC}}N\subset\operatorname{SEP},
LOCC are the "free operations" in the resource theories of entanglement: Entanglement cannot be produced from separable states with LOCC and if the local parties in addition to being able to perform all LOCC operations are also furnished with some entangled states, they can realize more operations than with LOCC alone.
LOCC operations are useful for state preparation, state discrimination, and entanglement transformations.
Alice and Bob are given a quantum system in the product state
|00\rangle=|0\rangleA ⊗ |0\rangleB
| \rho= | 1 | |00\rangle\langle00|+ |
| 2 |
| 1 | |
| 2 |
|11\rangle\langle11|
\rho
\rho
|1\rangleA
\rho
Given two quantum states
\psi
{\calH}={\calH}A ⊗ {\calH}B ⊗ ...{\calH}Z
\psi1,\psi2
|\psi1\rangle=
| 1 | |
| \sqrt{2 |
|\psi2\rangle=
| 1 | |
| \sqrt{2 |
Let's say the two-qubit system is separated, where the first qubit is given to Alice and the second is given to Bob. Without communication, Alice and Bob cannot distinguish the two states, since for all local measurements all measurement statistics are exactly the same (both states have the same reduced density matrix). E.g., assume that Alice measures the first qubit, and obtains the result 0. Since this result is equally likely to occur (with probability 50%) in each of the two cases, she does not gain any information on which Bell pair she was given and the same holds for Bob if he performs any measurement. But now let Alice send her result to Bob over a classical channel. Now Bob can compare his result to hers and if they are the same he can conclude that the pair given was
|\psi1\rangle
|0\rangleA ⊗ |0\rangleB
There are quantum states that cannot be distinguished with LOCC operations.[2]
While LOCC cannot generate entangled states out of product states, they can be used to transform entangled states into other entangled states. The restriction to LOCC severely limits which transformations are possible.
Nielsen [3] has derived a general condition to determine whether one pure state of a bipartite quantum system may be transformed into another using only LOCC. Full details may be found in the paper referenced earlier, the results are sketched out here.
Consider two particles in a Hilbert space of dimension
d
|\psi\rangle
|\phi\rangle
|\psi\rangle=\sumi\sqrt{\omegai}|iA\rangle ⊗ |iB\rangle
|\phi\rangle=\sumi\sqrt{\omegai'}|iA'\rangle ⊗ |iB'\rangle
The
\sqrt{\omegai}
\omega1>\omegad
|\psi\rangle
|\phi\rangle
k
1\leqk\leqd
| k\omega | |
| \sum | |
| i\leq\sum |
| k\omega | |
| i' |
In more concise notation:
|\psi\rangle → |\phi\rangle iff \omega\prec\omega'
This is a more restrictive condition than that local operations cannot increase entanglement measures. It is quite possible that
|\psi\rangle
|\phi\rangle
d
d
The operations described so far are deterministic, i.e., they succeed with probability 100%. If one is satisfied by probabilistic transformations, many more transformations are possible using LOCC.[4] These operations are called stochastic LOCC (SLOCC). In particular for multi-partite states the convertibility under SLOCC is studied to gain a qualitative insight into the entanglement properties of the involved states.[5]
If entangled states are available as a resource, these together with LOCC allow a much larger class of transformations. This is the case even if these resource states are not consumed in the process (as they are, for example, in quantum teleportation). Thus transformations are called entanglement catalysis.[6] In this procedure, the conversion of an initial state to a final state that is impossible with LOCC is made possible by taking a tensor product of the initial state with a "catalyst state"
|c\rangle
|\psi\rangle=\sqrt{0.4}|00\rangle+\sqrt{0.4}|11\rangle+\sqrt{0.1}|22\rangle+\sqrt{0.1}|33\rangle
|\phi\rangle=\sqrt{0.5}|00\rangle+\sqrt{0.25}|11\rangle+\sqrt{0.25}|22\rangle
|c\rangle=\sqrt{0.6}\mid\uparrow\uparrow\rangle+\sqrt{0.4}\mid\downarrow\downarrow\rangle
|\psi\rangle
|\phi\rangle
k | \psi\rangle | \phi\rangle | ||
| 0 | 0.4 | 0.5 | ||
| 1 | 0.8 | 0.75 | ||
| 2 | 0.9 | 1.0 | ||
| 3 | 1.0 | 1.0 |
| k\omega | |
| \sum | |
| i>\sum |
| k\omega' | |
| i |
| k\omega | |
| \sum | |
| i<\sum |
| k\omega' | |
| i |
| k\omega | |
| \sum | |
| i=\sum |
| k\omega' | |
| i |
|\psi\rangle
|\phi\rangle
k
|\psi\rangle
|\phi\rangle
|\phi\rangle
|\psi\rangle
Now we consider the product states
|\psi\rangle|c\rangle
|\phi\rangle|c\rangle
\begin{align}|\psi\rangle|c\rangle&= \sqrt{0.24}|00\rangle\mid\uparrow\uparrow\rangle+\sqrt{0.24}|11\rangle\mid\uparrow\uparrow\rangle+ \sqrt{0.16}|00\rangle\mid\downarrow\downarrow\rangle+\sqrt{0.16}|11\rangle\mid\downarrow\downarrow\rangle\\ &+\sqrt{0.06}|22\rangle\mid\uparrow\uparrow\rangle+\sqrt{0.06}|33\rangle\mid\uparrow\uparrow\rangle+ \sqrt{0.04}|22\rangle\mid\downarrow\downarrow\rangle+\sqrt{0.04}|33\rangle\mid\downarrow\downarrow\rangle\end{align}
\begin{align}|\phi\rangle|c\rangle&= \sqrt{0.30}|00\rangle\mid\uparrow\uparrow\rangle+\sqrt{0.20}|00\rangle\mid\downarrow\downarrow\rangle+ \sqrt{0.15}|11\rangle\mid\uparrow\uparrow\rangle+\sqrt{0.15}|22\rangle\mid\uparrow\uparrow\rangle\\ &+\sqrt{0.10}|11\rangle\mid\downarrow\downarrow\rangle+\sqrt{0.10}|22\rangle\mid\downarrow\downarrow\rangle\end{align}
k | \psi\rangle | c\rangle | \phi\rangle | c\rangle | ||
| 0 | 0.24 | 0.30 | ||||
| 1 | 0.48 | 0.50 | ||||
| 2 | 0.64 | 0.65 | ||||
| 3 | 0.80 | 0.80 | ||||
| 4 | 0.86 | 0.90 | ||||
| 5 | 0.92 | 1.00 | ||||
| 6 | 0.96 | 1.00 | ||||
| 7 | 1.00 | 1.00 |
k
|\psi\rangle|c\rangle
|\phi\rangle|c\rangle
|c\rangle
|\psi\rangle\overset{|c\rangle}{ → }|\phi\rangle
If correlations between the system and the catalyst are allowed, catalytic transformations between bipartite pure states are characterized via the entanglement entropy.[7] In more detail, a pure state
|\psi\rangle
|\phi\rangle
S(\psiA)\geqS(\phiA)
where
S
\psiA
\phiA
|\psi\rangle
|\phi\rangle