3.5 Entanglement
Entanglement is a consequence of quantum theory and leads to a correlation between the outcomes of measurements which cannot be explained by classical physics. Two-particle states which show such non-classical correlations are known as entangled states.
Consider the following thought experiment. Suppose you have a two-particle system in the spin state as given in Equation 10. Before the experiment you know that particle 1 can be either spin-up or spin-down with equal probability. However, if you measure particle 1 to be spin-up then you know that particle 2 is spin-down as the measurement means that the two-particle state has collapsed into the arrangement of spins. In contrast, if you measure particle 1 to be spin-down then you know that particle 2 is spin-up as the two-particle state has collapsed into the arrangement of spins. This type of prediction is quite puzzling because the two entangled particles can be as far apart as possible and when a measurement is made on particle 1 then it is known simultaneously what the outcome of a measurement on particle 2 will be.
Entanglement is essential for quantum computing. Entangled states are generated as part of the workings of a quantum computer, as you will see later.
Exercise 11
Confirm that the following states are normalised and determine whether the states are entangled.
- a.
- b.
Answer
The normalisation condition for a general two-particle state is that the sum of the squares of the probability amplitudes is equal to 1.
The states are entangled if the two-particle state cannot be factorised into the product of a particle 1 state multiplied by a particle 2 state.
a.Checking the normalisation of state :
showing state is normalised.
can also be factorised:
which is a particle 1 state multiplied by a particle 2 state so state is not entangled.
b.Checking the normalisation of state :
showing state is normalised.
State cannot be factorised and so is an entangled state.