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author | Prefetch | 2021-03-08 15:04:06 +0100 |
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committer | Prefetch | 2021-03-08 15:04:06 +0100 |
commit | 540d23bff03bedbc8f68287d71c8b5e7dc54b054 (patch) | |
tree | c3331ad86ea4be57e5c6c8385c9ac75b5dde6227 /content/know/concept/quantum-entanglement | |
parent | 7bf913f9bc7ab9f8f03c5530d245cf95e1edb43e (diff) |
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diff --git a/content/know/concept/quantum-entanglement/index.pdc b/content/know/concept/quantum-entanglement/index.pdc new file mode 100644 index 0000000..f8d0b76 --- /dev/null +++ b/content/know/concept/quantum-entanglement/index.pdc @@ -0,0 +1,152 @@ +--- +title: "Quantum entanglement" +firstLetter: "Q" +publishDate: 2021-03-07 +categories: +- Physics +- Quantum mechanics +- Quantum information + +date: 2021-03-07T15:36:15+01:00 +draft: false +markup: pandoc +--- + +# Quantum entanglement + +Consider a composite quantum system which consists of two subsystems $A$ and $B$, +respectively with basis states $\ket{a_n}$ and $\ket{b_n}$. +All accessible states of the sytem $\ket{\Psi}$ lie in +the tensor product of the subsystems' +[Hilbert spaces](/know/concept/hilbert-space/) $\mathbb{H}_A$ and $\mathbb{H}_B$: + +$$\begin{aligned} + \ket{\Psi} \in \mathbb{H}_A \otimes \mathbb{H}_B +\end{aligned}$$ + +A subset of these states can be written as the tensor product (i.e. Kronecker product in a basis) +of a state $\ket{\alpha}$ in $A$ and a state $\ket{\beta}$ in $B$, +often abbreviated as $\ket{\alpha} \ket{\beta}$: + +$$\begin{aligned} + \ket{\Psi} + = \ket{\alpha} \ket{\beta} + = \ket{\alpha} \otimes \ket{\beta} +\end{aligned}$$ + +The states that can be written in this way are called **separable**, +and states that cannot are called **entangled**. +Therefore, we are dealing with **quantum entanglement** +if the state of subsystem $A$ cannot be fully described +independently of the state of subsystem $B$, and vice versa. + +To detect and quantify entanglement, +we can use the [density operator](/know/concept/density-operator/) $\hat{\rho}$. +For a pure ensemble in a given (possibly entangled) state $\ket{\Psi}$, +$\hat{\rho}$ is given by: + +$$\begin{aligned} + \hat{\rho} = \ket{\Psi} \bra{\Psi} +\end{aligned}$$ + +From this, we would like to extract the corresponding state of subsystem $A$. +For that purpose, we define the **reduced density operator** $\hat{\rho}_A$ of subsystem $A$ as follows: + +$$\begin{aligned} + \boxed{ + \hat{\rho}_A + = \Tr_B(\hat{\rho}) + = \sum_m \bra{b_m} \Big( \hat{\rho} \Big) \ket{b_m} + } +\end{aligned}$$ + +Where $\Tr_B(\hat{\rho})$ is called the **partial trace** of $\hat{\rho}$, +which basically eliminates subsystem $B$ from $\hat{\rho}$. +For a pure composite state $\ket{\Psi}$, +the resulting $\hat{\rho}_A$ describes a pure state in $A$ if $\ket{\Psi}$ is separable, +else, if $\ket{\Psi}$ is entangled, it describes a mixed state in $A$. +In the former case we simply find: + +$$\begin{aligned} + \boxed{ + \ket{\Psi} = \ket{\alpha} \otimes \ket{\beta} + \quad \implies \quad + \hat{\rho}_A = \ket{\alpha} \bra{\alpha} + } +\end{aligned}$$ + +We call $\ket{\Psi}$ **maximally entangled** +if its reduced density operators are **maximally mixed**, +where $N$ is the dimension of $\mathbb{H}_A$ and $\hat{I}$ is the identity matrix: + +$$\begin{aligned} + \hat{\rho}_A + = \frac{1}{N} \hat{I} +\end{aligned}$$ + +Suppose that we are given an entangled pure state +$\ket{\Psi} \neq \ket{\alpha} \otimes \ket{\beta}$. +Then the partial traces $\hat{\rho}_A$ and $\hat{\rho}_B$ +of $\hat{\rho} = \ket{\Psi} \bra{\Psi}$ are mixed states with the same probabilities $p_n$ +(assuming $\mathbb{H}_A$ and $\mathbb{H}_B$ have the same dimensions, +which is usually the case): + +$$\begin{aligned} + \hat{\rho}_A + = \Tr_B(\hat{\rho}) + = \sum_n p_n \ket{a_n} \bra{a_n} + \qquad \quad + \hat{\rho}_B + = \Tr_A(\hat{\rho}) + = \sum_n p_n \ket{b_n} \bra{b_n} +\end{aligned}$$ + +There exists an orthonormal choice +of the subsystem basis states $\ket{a_n}$ and $\ket{b_n}$, +such that $\ket{\Psi}$ can be written as follows, +where $p_n$ are the probabilities in the reduced density operators: + +$$\begin{aligned} + \ket{\Psi} + = \sum_n \sqrt{p_n} \Big( \ket{a_n} \otimes \ket{b_n} \Big) +\end{aligned}$$ + +This is the **Schmidt decomposition**, +and the **Schmidt number** is the number of nonzero terms in the summation, +which can be used to determine if the state $\ket{\Psi}$ +is entangled (greater than one) or separable (equal to one). + +By looking at the Schmidt decomposition, we can notice that, +if $\hat{O}_A$ and $\hat{O}_B$ are the subsystem observables +with basis eigenstates $\ket{a_n}$ and $\ket{b_n}$, +then measurement results of these operators +will be perfectly correlated across $A$ and $B$. +This is a general property of entangled systems, +but beware: correlation does not imply entanglement! + +But what if the composite system is in a mixed state $\hat{\rho}$? +The state is separable if and only if: + +$$\begin{aligned} + \boxed{ + \hat{\rho} + = \sum_m p_m \Big( \hat{\rho}_A \otimes \hat{\rho}_B \Big) + } +\end{aligned}$$ + +Where $p_m$ are probabilities, +and $\hat{\rho}_A$ and $\hat{\rho}_B$ can be any subsystem states. +In reality, it is very hard to determine, using this criterium, +whether an arbitrary given $\hat{\rho}$ is separable or not. + +As a final side note, the expectation value +of an obervable $\hat{O}_A$ acting only on $A$ is given by: + +$$\begin{aligned} + \expval*{\hat{O}_A} + = \Tr\big(\hat{\rho} \hat{O}_A\big) + = \Tr_A\big(\Tr_B(\hat{\rho} \hat{O}_A)\big) + = \Tr_A\big(\Tr_B(\hat{\rho}) \hat{O}_A)\big) + = \Tr_A\big(\hat{\rho}_A \hat{O}_A\big) +\end{aligned}$$ + |