Bell’s inequalities and non-locality

Bell’s original work, and many subsequent variants show how quantum

correlations in an entangled state are essentially different from classical ones.

One of the inequalities of Bell applies to a physical system consisting of two

subsystems, obeying the principle of local realism. He shows that the quantum

statistics for such a system involving entangled subsystems will necessarily vi-

olate this inequality, a statement generically known as “Bell’s theorem” [64].

Subsequently many similar inequalities were discovered by various authors.

(These are reviewed in [18].) We will discuss one of them (not Bell’s original

one!) to show how quantum correlations are intrinsically different from classi-

cal (local realist) ones. This follows original work by Clauser, Horne, Shimony

and Holt [17](CHSH).

We consider spin as an example but the derivation holds true for any

dichotomic variable, i.e., one with measurements outcomes described by two

values, ±1. Let’s revisit the experiment of Figure 4.2.

Consider a source emitting a very large number N of entangled spin-half

pairs, and four arbitrary directions ˆa,

ˆ

a

0

,

ˆ

b,

ˆ

b

0

for SG machines chosen by Alice

and Bob for measuring. Suppose that before measurement, the spin of the i

th

pair has hidden, fixed values r

i

(a) and r

i

(a

0

) for particle (1), s

i

(b) and s

i

(b

0

)

for particle (2) along the respective axes. The correlation between particles

(1) and (2) can be measured by the average value of the product of spin

measurements:

C(a, b) =

1

N

X

i

r

i

(a)s

i

(b). (4.14)

We will have similar expressions for C(a

0

, b), C(a, b

0

), and C(a

0

, b

0

), if the ex-

periments used those pairs of axes for measurement. These expressions for the

average are the same as for classical statistical averages.

CHSH in their worked aimed to calculate the quantity

C(a, b) + C(a, b

0

) + C(a

0

, b) − C(a

0

, b

0

). (4.15)

We’ll first see what the “classical” value is, assuming hidden variable descrip-

tion and then compare it with the predictions of quantum mechanics. First

look at the possible combinations of spin values (in units of ~/2) for the i

th

pair. We introduce the notation

T

1

= r

i

(a)[s

i

(b) + s

i

(b

0

)], T

2

= r

i

(a

0

)[s

i

(b) − s

i

(b

0

)].

74 Introduction to Quantum Physics and Information Processing

Observe that T

1

+ T

2

= ±2 always. For instance, when r

i

(a) = +1, r

i

(a

0

) =

−1, s

i

(b) = −1, s

i

(b

0

) = +1, then T

1

= −2 and T

2

= 0. You can see similar

results for all other combinations of values for these two spin measurements.

To evaluate the sum 4.15, we just sum T

1

+ T

2

over all i and divide by N:

|C(a, b) + C(a, b

0

) + C(a

0

, b) − C(a

0

, b

0

)| ≤ 2.. (4.16)

This is the CHSH inequality.

What does quantum mechanics predict for the sum (4.15)? Remember that

the spins are not to have fixed values before measurement. The correlation

between spins are now the quantum mechanical expectation values of spin

operator products in the state of Equation 4.13:

C(a, b) = h

ˆ

S

a

ˆ

S

b

i

β

11

. (4.17)

Note that the operator

ˆ

S

a

, spin along direction ˆa is just ~σ ·ˆa (in units of ~/2).

You would have shown in Problem 3.12 (b) of Chapter 3, that the eigenvectors

of

ˆ

S

a

are given by

|ˆa±i = e

−i

ˆ

k·~σ

|Z±i.

Here

ˆ

k is a direction perpendicular to both ˆz and ˆa, i.e., parallel to ˆz × ˆa.

Example 4.4.1. Let’s find the expectation value of

ˆ

S

a

ˆ

S

b

in the Bell state

|β

11

i.

ˆ

S

a

|β

11

i = ~σ · ˆa(|01i − |10i)

= (a

x

X

1

+ a

y

Y

1

+ a

z

Z

1

)(|01i − |10i)

= a

x

(|11i − |00i) − ia

y

(|01i + |10i) + a

z

(|01i + |10i)

ˆ

S

a

ˆ

S

b

|β

11

i = −a

x

b

x

|β

11

i − ia

x

b

y

(|10i + |01i) + a

x

b

z

(|10i + |11i)

−ia

y

b

x

(|00i + |11i) − a

y

b

y

|β

11

i + ia

y

b

z

(|01i − |10i)

+a

z

b

x

(|11i + |00i) + ia

z

b

y

(|01i − |10i) − a

z

b

z

|β

11

i,

hβ

11

|

ˆ

S

a

ˆ

S

b

|β

11

i = −a

x

b

x

− a

y

b

y

− a

z

b

z

= −ˆa ·

ˆ

b.

Then the left-hand side of Equation 4.16 is

|ˆa · (

ˆ

b +

ˆ

b

0

) +

ˆ

a

0

· (

ˆ

b −

ˆ

b

0

)| ≤ |ˆa||

ˆ

b +

ˆ

b

0

| + |

ˆ

a

0

||

ˆ

b −

ˆ

b

0

| (4.18)

=

√

2(

p

1 + cos φ +

p

1 − cos φ)(4.19)

where cos φ =

ˆ

b ·

ˆ

b

0

. (4.20)

Now the minimum value this can take is obviously when cos φ = 0, and that

value is 2

√

2, greater than the CHSH bound. Thus there exist configurations

Properties of Qubits 75

of detectors that can violate the CHSH inequality. See for instance Figure

4.3. This leads us to conclude that quantum mechanics is NOT compatible

with a local realistic description, that is, the assumption that the spins have

values before they are measured must be wrong. The entangled state vector

describes the pair as a single whole, with no room for describing the states

of the individual constituents. They have no well-defined spin in such a state.

There is therefore no way of setting about deriving the CHSH inequality for

such a system: the spin values of particles (1) and (2) do not exist before they

are measured.

Example 4.4.2. Let’s examine the directions for which the CHSH inequality is

maximally violated. If cos φ = 0, then we have

ˆ

b ⊥

ˆ

b

0

. The RHS of inequality

4.18 also shows that ˆa and

ˆ

b +

ˆ

b

0

must be parallel or antiparallel, and so

also

ˆ

a

0

and

ˆ

b −

ˆ

b

0

must be parallel or antiparallel. One way of picking such

directions is for Alice to choose ˆz and ˆx while Bob chooses the ±45

◦

directions

(

1

√

2



ˆx + ˆz



and

1

√

2



ˆz − ˆx



), as in Figure 4.3. Other sets of combinations are

also possible that satisfy the above criterion (find them!). In the language

of quantum mechanics, we must speak of the operators corresponding to the

measurement axes of A and B: in other words, we talk of then measuring

the operator σ

a

or σ

b

. Thus we speak of correlations between certain pairs of

observables that violate the CHSH bound for classical correlations.

FIGURE 4.3: Directions for SG detectors a, a

0

, b and b

0

and the corresponding

observables measured by Alice and Bob, that maximally violate the CHSH

inequality.

The beauty of Bell’s inequalities was that for the first time they provided a

way to test quantum mechanics experimentally. The first experimental realiza-

tion of this was performed by the group led by Alain Aspect in 1981 [2]. Since

then, many experiments have been performed that confirm the violation of

the inequalities, and the corresponding interpretation of quantum mechanics

as theory that intrinsically does not obey “local realism”.

However, some researchers have tried to come up with non-local theories

that still are consistent with relativity, notably the GRW [37] theory of Ghi-

76 Introduction to Quantum Physics and Information Processing

rardi, Rimini, and Weber, and Bohmian mechanics [22]. The debate still con-

tinues as people come up with plausible non-local realistic theories to replace

quantum mechanics!

This section ought to have convinced you that quantum entanglement is

something new and more than classical correlations: leading to its exploitation

as a resource in information processing.

Many of the original papers cited in this chapter are reprinted in an in-

valuable volume by Wheeler and Zurek [72]. A wonderful discussion of many

of the properties of quantum systems discussed here is given in the book by

Aharonov and Rohrlich [1].

Problems

4.1. Find out what the action of each of the σ

i

operators is on the Bloch sphere

by checking their effects on the eigenvectors |Z±i, |X±i and |Y ±i.

4.2. Prove that the Bell states are mutually orthogonal and that they form

a basis for H

2

. You must be able to express an arbitrary 2-qubit state

|ψi = a|00i + b|01i + c|10i + d|11i as a linear superposition of the Bell

states. Find the coefficients in this superposition in terms of a, b, c, and d.

4.3. Entanglement and basis change: suppose |s

1

i and |s

2

i, linear combinations

of the basis states |0i and |1i form an orthonormal basis for a spin Hilbert

space. Show that the two-spin entangled “singlet” state

1

√

2

(|s

1

i ⊗ |s

2

i − |s

2

i ⊗ |s

1

i)

is equivalent to

1

√

2

(|01i − |10i).

Check that this preservation of the form of entanglement does not hold for

the other three Bell states in the transformed basis.

4.4. We found the directions ˆa,

ˆ

a

0

,

ˆ

b, and

ˆ

b

0

of Stern–Gerlach machines for

which the CHSH inequality is maximally violated for spin half particles.

Translate this experiment to photon polarization measurements and find

the corresponding directions for the axes of polarizers used by Alice and

Bob that would maximally violate the CHSH inequality.