Fock state

In quantum mechanics, a Fock state or number state is a quantum state that is an element of a Fock space with a well-defined number of particles (or quanta). These states are named after the Soviet physicist Vladimir Fock. Fock states play an important role in the second quantization formulation of quantum mechanics.

The particle representation was first treated in detail by Paul Dirac for bosons and by Pascual Jordan and Eugene Wigner for fermions.^[1]^: 35 The Fock states of bosons and fermions obey useful relations with respect to the Fock space creation and annihilation operators.

Definition

One specifies a multiparticle state of N non-interacting identical particles by writing the state as a sum of tensor products of N one-particle states. Additionally, depending on the integrality of the particles' spin, the tensor products must be alternating (anti-symmetric) or symmetric products of the underlying one-particle Hilbert space. Specifically:

Fermions, having half-integer spin and obeying the Pauli exclusion principle, correspond to antisymmetric tensor products.
Bosons, possessing integer spin (and not governed by the exclusion principle) correspond to symmetric tensor products.

If the number of particles is variable, one constructs the Fock space as the direct sum of the tensor product Hilbert spaces for each particle number. In the Fock space, it is possible to specify the same state in a new notation, the occupancy number notation, by specifying the number of particles in each possible one-particle state.

Let ${\textstyle \left\{\mathbf {k} _{i}\right\}_{i\in I}}$ be an orthonormal basis of states in the underlying one-particle Hilbert space. This induces a corresponding basis of the Fock space called the "occupancy number basis". A quantum state in the Fock space is called a Fock state if it is an element of the occupancy number basis.

A Fock state satisfies an important criterion: for each i, the state is an eigenstate of the particle number operator ${\widehat {N_{{\mathbf {k} }_{i}}}}$ corresponding to the i-th elementary state k_i. The corresponding eigenvalue gives the number of particles in the state. This criterion nearly defines the Fock states (one must in addition select a phase factor).

A given Fock state is denoted by $|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},..n_{{\mathbf {k} }_{i}}...\rangle$ . In this expression, $n_{{\mathbf {k} }_{i}}$ denotes the number of particles in the i-th state k_i, and the particle number operator for the i-th state, ${\widehat {N_{{\mathbf {k} }_{i}}}}$ , acts on the Fock state in the following way:

{\widehat {N_{{\mathbf {k} }_{i}}}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},..n_{{\mathbf {k} }_{i}}...\rangle =n_{{\mathbf {k} }_{i}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},..n_{{\mathbf {k} }_{i}}...\rangle

Hence the Fock state is an eigenstate of the number operator with eigenvalue $n_{{\mathbf {k} }_{i}}$ .^[2]^: 478

Fock states often form the most convenient basis of a Fock space. Elements of a Fock space that are superpositions of states of differing particle number (and thus not eigenstates of the number operator) are not Fock states. For this reason, not all elements of a Fock space are referred to as "Fock states".

If we define the aggregate particle number operator ${\textstyle {\widehat {N}}}$ as

{\widehat {N}}=\sum _{i}{\widehat {N_{{\mathbf {k} }_{i}}}},

the definition of Fock state ensures that the variance of measurement $\operatorname {Var} \left({\widehat {N}}\right)=0$ , i.e., measuring the number of particles in a Fock state always returns a definite value with no fluctuation.

Example using two particles

For any final state $|f\rangle$ , any Fock state of two identical particles given by $|1_{\mathbf {k} _{1}},1_{\mathbf {k} _{2}}\rangle$ , and any operator ${\widehat {\mathbb {O} }}$ , we have the following condition for indistinguishability:^[3]^: 191

\left|\left\langle f\left|{\widehat {\mathbb {O} }}\right|1_{\mathbf {k} _{1}},1_{\mathbf {k} _{2}}\right\rangle \right|^{2}=\left|\left\langle f\left|{\widehat {\mathbb {O} }}\right|1_{\mathbf {k} _{2}},1_{\mathbf {k} _{1}}\right\rangle \right|^{2}

.

So, we must have $\left\langle f\left|{\widehat {\mathbb {O} }}\right|1_{\mathbf {k} _{1}},1_{\mathbf {k} _{2}}\right\rangle =e^{i\delta }\left\langle f\left|{\widehat {\mathbb {O} }}\right|1_{\mathbf {k} _{2}},1_{\mathbf {k} _{1}}\right\rangle$

where $e^{i\delta }=+1$ for bosons and $-1$ for fermions. Since $\langle f|$ and ${\widehat {\mathbb {O} }}$ are arbitrary, we can say,

\left|1_{\mathbf {k} _{1}},1_{\mathbf {k} _{2}}\right\rangle =+\left|1_{\mathbf {k} _{2}},1_{\mathbf {k} _{1}}\right\rangle

for bosons and

\left|1_{\mathbf {k} _{1}},1_{\mathbf {k} _{2}}\right\rangle =-\left|1_{\mathbf {k} _{2}},1_{\mathbf {k} _{1}}\right\rangle

for fermions.^[3]^: 191

Note that the number operator does not distinguish bosons from fermions; indeed, it just counts particles without regard to their symmetry type. To perceive any difference between them, we need other operators, namely the creation and annihilation operators.

Bosonic Fock state

Bosons, which are particles with integer spin, follow a simple rule: their composite eigenstate is symmetric^[4] under operation by an exchange operator. For example, in a two particle system in the tensor product representation we have ${\hat {P}}\left|x_{1},x_{2}\right\rangle =\left|x_{2},x_{1}\right\rangle$ .

Boson creation and annihilation operators

We should be able to express the same symmetric property in this new Fock space representation. For this we introduce non-Hermitian bosonic creation and annihilation operators,^[4] denoted by $b^{\dagger }$ and $b$ respectively. The action of these operators on a Fock state are given by the following two equations:

Creation operator ${\textstyle b_{{\mathbf {k} }_{l}}^{\dagger }}$ :
$b_{{\mathbf {k} }_{l}}^{\dagger }|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}},...\rangle ={\sqrt {n_{{\mathbf {k} }_{l}}+1}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}}+1,...\rangle$ ^[4]
Annihilation operator ${\textstyle b_{{\mathbf {k} }_{l}}}$ :
$b_{{\mathbf {k} }_{l}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}},...\rangle ={\sqrt {n_{{\mathbf {k} }_{l}}}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}}-1,...\rangle$ ^[4]

*The Operation of creation and annihilation operators on Bosonic Fock states.*

Non-Hermiticity of creation and annihilation operators

The bosonic Fock state creation and annihilation operators are not Hermitian operators.^[4]

Proof that creation and annihilation operators are not Hermitian.

For a Fock state, $|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}},\dots \rangle$ , ${\begin{aligned}\left\langle n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}}-1,\dots \left|b_{\mathbf {k} _{l}}\right|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}},\dots \right\rangle &={\sqrt {n_{\mathbf {k} _{l}}}}\left\langle n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}}-1,\dots |n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}}-1,\dots \right\rangle \\[6pt]\left(\left\langle n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}},\dots \left|b_{\mathbf {k} _{l}}\right|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}}-1,\dots \right\rangle \right)^{*}&=\left\langle n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}}-1\dots \left|b_{\mathbf {k} _{l}}^{\dagger }\right|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}},\dots \right\rangle \\&={\sqrt {n_{\mathbf {k} _{l}}+1}}\left\langle n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}}-1\dots |n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},n_{\mathbf {k} _{3}}\dots n_{\mathbf {k} _{l}}+1\dots \right\rangle \end{aligned}}$

Therefore, it is clear that adjoint of creation (annihilation) operator doesn't go into itself. Hence, they are not Hermitian operators.

But adjoint of creation (annihilation) operator is annihilation (creation) operator.^[5]^: 45

Operator identities

The commutation relations of creation and annihilation operators in a bosonic system are

\left[b_{i}^{\,},b_{j}^{\dagger }\right]\equiv b_{i}^{\,}b_{j}^{\dagger }-b_{j}^{\dagger }b_{i}^{\,}=\delta _{ij},

^[4]

\left[b_{i}^{\dagger },b_{j}^{\dagger }\right]=\left[b_{i}^{\,},b_{j}^{\,}\right]=0,

^[4]

where $[\ \ ,\ \ ]$ is the commutator and $\delta _{ij}$ is the Kronecker delta.

N bosonic basis states

Number of particles (N)	Bosonic basis states^[6]^: 11
0	$\|0,0,0...\rangle$
1	$\|1,0,0...\rangle$ , $\|0,1,0...\rangle$ , $\|0,0,1...\rangle$ ,...
2	$\|2,0,0...\rangle$ , $\|1,1,0...\rangle$ , $\|0,2,0...\rangle$ ,...
$n$	$\|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}},...\rangle$

Action on some specific Fock states

For a vacuum state—no particle is in any state— expressed as $|0_{{\mathbf {k} }_{1}},0_{{\mathbf {k} }_{2}},0_{{\mathbf {k} }_{3}}...0_{{\mathbf {k} }_{l}},...\rangle$ , we have:
$b_{{\mathbf {k} }_{l}}^{\dagger }|0_{{\mathbf {k} }_{1}},0_{{\mathbf {k} }_{2}},0_{{\mathbf {k} }_{3}}...0_{{\mathbf {k} }_{l}},...\rangle =|0_{{\mathbf {k} }_{1}},0_{{\mathbf {k} }_{2}},0_{{\mathbf {k} }_{3}}...1_{{\mathbf {k} }_{l}},...\rangle$
and, $b_{\mathbf {k} _{l}}|0_{\mathbf {k} _{1}},0_{\mathbf {k} _{2}},0_{\mathbf {k} _{3}}...0_{\mathbf {k} _{l}},...\rangle =0$ .^[4] That is, the l-th creation operator creates a particle in the l-th state k_l, and the vacuum state is a fixed point of annihilation operators as there are no particles to annihilate.
We can generate any Fock state by operating on the vacuum state with an appropriate number of creation operators:
$|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}}...\rangle ={\frac {\left(b_{\mathbf {k} _{1}}^{\dagger }\right)^{n_{\mathbf {k} _{1}}}}{\sqrt {n_{\mathbf {k} _{1}}!}}}{\frac {\left(b_{\mathbf {k} _{2}}^{\dagger }\right)^{n_{\mathbf {k} _{2}}}}{\sqrt {n_{\mathbf {k} _{2}}!}}}...|0_{\mathbf {k} _{1}},0_{\mathbf {k} _{2}},...\rangle$
For a single mode Fock state, expressed as, $|n_{\mathbf {k} }\rangle$ ,
$b_{\mathbf {k} }^{\dagger }|n_{\mathbf {k} }\rangle ={\sqrt {n_{\mathbf {k} }+1}}|n_{\mathbf {k} }+1\rangle$ and,

$b_{\mathbf {k} }|n_{\mathbf {k} }\rangle ={\sqrt {n_{\mathbf {k} }}}|n_{\mathbf {k} }-1\rangle$

Action of number operators

The number operators ${\textstyle {\widehat {N_{{\mathbf {k} }_{l}}}}}$ for a bosonic system are given by ${\widehat {N_{{\mathbf {k} }_{l}}}}=b_{{\mathbf {k} }_{l}}^{\dagger }b_{{\mathbf {k} }_{l}}$ , where ${\widehat {N_{{\mathbf {k} }_{l}}}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}}...\rangle =n_{{\mathbf {k} }_{l}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}}...\rangle$ ^[4]

Number operators are Hermitian operators.

Symmetric behaviour of bosonic Fock states

The commutation relations of the creation and annihilation operators ensure that the bosonic Fock states have the appropriate symmetric behaviour under particle exchange. Here, exchange of particles between two states (say, l and m) is done by annihilating a particle in state l and creating one in state m. If we start with a Fock state $|\psi \rangle =\left|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},....n_{\mathbf {k} _{m}}...n_{\mathbf {k} _{l}}...\right\rangle$ , and want to shift a particle from state $k_{l}$ to state $k_{m}$ , then we operate the Fock state by $b_{\mathbf {k} _{m}}^{\dagger }b_{\mathbf {k} _{l}}$ in the following way:

Using the commutation relation we have, $b_{\mathbf {k} _{m}}^{\dagger }.b_{\mathbf {k} _{l}}=b_{\mathbf {k} _{l}}.b_{\mathbf {k} _{m}}^{\dagger }$

{\begin{aligned}b_{\mathbf {k} _{m}}^{\dagger }.b_{\mathbf {k} _{l}}\left|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},....n_{\mathbf {k} _{m}}...n_{\mathbf {k} _{l}}...\right\rangle &=b_{\mathbf {k} _{l}}.b_{\mathbf {k} _{m}}^{\dagger }\left|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},....n_{\mathbf {k} _{m}}...n_{\mathbf {k} _{l}}...\right\rangle \\&={\sqrt {n_{\mathbf {k} _{m}}+1}}{\sqrt {n_{\mathbf {k} _{l}}}}\left|n_{\mathbf {k} _{1}},n_{\mathbf {k} _{2}},....n_{\mathbf {k} _{m}}+1...n_{\mathbf {k} _{l}}-1...\right\rangle \end{aligned}}

So, the Bosonic Fock state behaves to be symmetric under operation by Exchange operator.

Wigner function of $|0\rangle$
Wigner function of $|1\rangle$
Wigner function of $|2\rangle$
Wigner function of $|3\rangle$
Wigner function of $|4\rangle$

Fermionic Fock state

Fermion creation and annihilation operators

To be able to retain the antisymmetric behaviour of fermions, for Fermionic Fock states we introduce non-Hermitian fermion creation and annihilation operators,^[4] defined for a Fermionic Fock state $|\psi \rangle =|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}},...\rangle$ as:^[4]

The creation operator $c_{{\mathbf {k} }_{l}}^{\dagger }$ acts as:
$c_{{\mathbf {k} }_{l}}^{\dagger }|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}},...\rangle ={\sqrt {n_{{\mathbf {k} }_{l}}+1}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}}+1,...\rangle$ ^[4]
The annihilation operator ${\textstyle c_{{\mathbf {k} }_{l}}}$ acts as:
$c_{{\mathbf {k} }_{l}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}},...\rangle ={\sqrt {n_{{\mathbf {k} }_{l}}}}|n_{{\mathbf {k} }_{1}},n_{{\mathbf {k} }_{2}},n_{{\mathbf {k} }_{3}}...n_{{\mathbf {k} }_{l}}-1,...\rangle$

These two actions are done antisymmetrically, which we shall discuss later.