Translation operator (quantum mechanics) explained

In quantum mechanics, a translation operator is defined as an operator which shifts particles and fields by a certain amount in a certain direction. It is a special case of the shift operator from functional analysis.

, there is a corresponding translation operator

\hat{T}(x)

that shifts particles and fields by the amount

For example, if

\hat{T}(x)

acts on a particle located at position

, the result is a particle at position

r+x

Translation operators are unitary.

Translation operators are closely related to the momentum operator; for example, a translation operator that moves by an infinitesimal amount in the

direction has a simple relationship to the

-component of the momentum operator. Because of this relationship, conservation of momentum holds when the translation operators commute with the Hamiltonian, i.e. when laws of physics are translation-invariant. This is an example of Noether's theorem.

Action on position eigenkets and wavefunctions

The translation operator

\hat{T}(x)

moves particles and fields by the amount

. Therefore, if a particle is in an eigenstate

|r\rangle

of the position operator (i.e., precisely located at the position

), then after

\hat{T}(x)=\intdr~|r+x\rangle\langler|

acts on it, the particle is at the position

r+x

\hat(\mathbf)|\mathbf\rangle = |\mathbf+\mathbf\rangle .

An alternative (and equivalent) way to describe what the translation operator determines is based on position-space wavefunctions. If a particle has a position-space wavefunction

\psi(r)

, and

\hatT(x)

acts on the particle, the new position-space wavefunction is

\psi'(r)=\hatT(x)\psi(r)

defined by

\psi'(\mathbf) = \psi(\mathbf - \mathbf).

This relation is easier to remember as

\psi'(r+x)=\psi(r),

which can be read as: "The value of the new wavefunction at the new point equals the value of the old wavefunction at the old point".^[1]

Here is an example showing that these two descriptions are equivalent. The state

|a\rangle

corresponds to the wavefunction

\psi(r)=\delta(r-a)

(where

\delta

is the Dirac delta function), while the state

\hat{T}(x)|a\rangle=|a+x\rangle

corresponds to the wavefunction

\psi'(r)=\delta(r-(a+x)).

These indeed satisfy

\psi'(r)=\psi(r-x).

Momentum as generator of translations

See also: Shift operator and Momentum operator. In introductory physics, momentum is usually defined as mass times velocity. However, there is a more fundamental way to define momentum, in terms of translation operators. This is more specifically called canonical momentum, and it is usually but not always equal to mass times velocity. One notable exception pertains to a charged particle in a magnetic field in which the canonical momentum includes both the usual momentum and a second terms proportional to the magnetic vector potential.^[1] This definition of momentum is especially important because the law of conservation of momentum applies only to canonical momentum, and is not universally valid if momentum is defined instead as mass times velocity (the so-called "kinetic momentum"), for reasons explained below.

The (canonical) momentum operator is defined as the gradient of the translation operators near the origin:where

\hbar

is the reduced Planck constant. For example, what is the result when the

\hat{p}_x

operator acts on a quantum state? To find the answer, translate the state by an infinitesimal amount in the

-direction, calculate the rate that the state is changing, and multiply the result by

i\hbar

. For example, if a state does not change at all when it is translated an infinitesimal amount the

-direction, then its

-component of momentum is 0.

More explicitly,

\hat{p

} is a vector operator (i.e. a vector operator consisting of three operators

(\hat{p}_x,\hat{p}_y,\hat{p}_z)

components is given by:

\hat_x = i\hbar \lim_ \frac

where

\hat{I

} is the identity operator and

\hat{x

} is the unit vector in the

-direction. (

\hat{p}_y

and

\hat{p}_z

are defined analogously.)

The equation above is the most general definition of

\hat{p

}. In the special case of a single particle with wavefunction

\psi(r)

\hat{p

} can be written in a more specific and useful form. In one dimension:

\begin(\hat\psi)(r) &= i\hbar \lim_ \frac \\&= i\hbar \lim_ \frac \\ &= -i\hbar \frac \psi(r).\end

While in three dimensions,

\mathbf = -i\hbar \nabla

as an operator acting on position-space wavefunctions. This is the familiar quantum-mechanical expression for

\hat{p

}, but we have derived it here from a more basic starting point.

We have now defined

\hat{p

} in terms of translation operators. It is also possible to write a translation operator as a function of

\hat{p

}. The method consists of considering an infinitesimal action on a wavefunction, and expanding the transformed wavefunction as a sum of the initial wavefunction and a first-order perturbative correction; and then expressing a finite translation as a huge number

of consecutive tiny translations, and then use the fact that infinitesimal translations can be written in terms of

\hat{p

}. From what has been stated previously, we know from above that if

\widehat{T}(dx)

acts on

\psi(r)

that the result is

\begin\psi'(\mathbf) = \psi(\mathbf - d\mathbf) .\end

The right-hand side may be written as a Taylor series

\begin \psi(\mathbf) - d\mathbf\cdot \frac + \frac\left(d\mathbf\right)^2\left(\frac\right)^2 + \cdots .\end

We suppose that for an infinitesimal translation that the higher-order terms in the series become successively smaller. From which we write

\begin\psi'(\mathbf) = \psi(\mathbf) - d\mathbf\cdot \frac = \left(1 - \frac \right)\psi(\mathbf) .\end

With this preliminary result, we proceed to write the an infinite amount of infinitesimal actions as

\begin\hat T(\mathbf x) &=\lim_ (\hat T(\mathbf/N))^N \\& = \lim_ \left[1-\frac{i\mathbf{x}\cdot\mathbf\hat{p}}{N\hbar}\right]^N\end.

The right-hand side is precisely a series for an exponential. Hence, where

\exp

is the operator exponential and the right-hand side is the Taylor series expansion. For very small

, one can use the approximation:

\hat T(\mathbf x) \approx 1 - i \mathbf x \cdot \mathbf / \hbar ~~\text~~\mathbf \to \mathbf

The operator equation

\exp\left(-x ⋅	i\hatp
	\hbar

\right)\psi(r)=\psi(r-x)

is an operator version of Taylor's theorem; and is, therefore, only valid under caveats about

\psi

being an analytic function. Concentrating on the operator part, it shows that

	i\hatp
	\hbar

is an infinitesimal transformation, generating translations of the real line via the exponential.It is for this reason that the momentum operator is referred to as the generator of translation.^[2]

A nice way to double-check that these relations are correct is to do a Taylor expansion of the translation operator acting on a position-space wavefunction. Expanding the exponential to all orders, the translation operator generates exactly the full Taylor expansion of a test function: $\begin\psi(\mathbf-\mathbf)& =\hat T(\mathbf x)\psi(\mathbf)\\& =\exp\left(-\frac\right)\psi(\mathbf)\\& =\left(\sum_^ \frac(-\frac\mathbf\cdot\mathbf)^n\right)\psi(\mathbf)\\& =\left(\sum_^ \frac(-\mathbf\cdot\mathbf)^n\right)\psi(\mathbf)\\& =\psi(\mathbf)-\mathbf\cdot\mathbf\psi(\mathbf)+\frac(\mathbf\cdot\mathbf)^2\psi(\mathbf)-\dots\end$ So every translation operator generates exactly the expected translation on a test function if the function is analytic in some domain of the complex plane.

Properties

Successive translations

$\hat T(\mathbf_1) \hat T(\mathbf_2) = \hat T(\mathbf_1 + \mathbf_2)$

In other words, if particles and fields are moved by the amount

x₂

and then by the amount

x₁

, overall they have been moved by the amount

x₁+x₂

. For a mathematical proof, one can look at what these operators do to a particle in a position eigenstate:

\hat T(\mathbf_1) \hat T(\mathbf_2) |\mathbf\rangle = \hat T(\mathbf_1) |\mathbf_2 + \mathbf\rangle = |\mathbf_1 + \mathbf_2 + \mathbf\rangle = \hat T(\mathbf_1 + \mathbf_2)|\mathbf\rangle

Since the operators

\hatT(x₁₎\hatT(x₂₎

and

\hatT(x₁+x₂₎

have the same effect on every state in an eigenbasis, it follows that the operators are equal.

Identity translation

The translation

\hatT(0)=\hat{I

}, i.e. a translation by a distance of 0 is the same as the identity operator which leaves all states unchanged.

Inverse

The translation operators are invertible, and their inverses are: $(\hat T(\mathbf))^ = \hat T(-\mathbf)$

This follows from the "successive translations" property above, and the identity translation.

Translation operators commute with each other

$\hat T(\mathbf)\hat T(\mathbf) = \hat T(\mathbf)\hat T(\mathbf)$ because both sides are equal to

\hatT(x+y)

.^[1]

Translation operators are unitary

To show that translation operators are unitary, we first must prove that the momentum operator

\widehat{p}

is Hermitian. Then, we can prove that the translation operator meets two criteria that are necessary to be a unitary operator.

To begin with, the linear momentum operator

\widehat{p}:L^{2([-infty,infty],\mu)\to}L^{2([-infty,infty],\mu)}

is the rule that assigns to any

\psi(r)

in the domain the one vector

\psi'(r) = \left[\widehat{p}\psi\right](r) = \left[-i\hbar \frac{d}{dx}\psi\right](r)

in the codomain is. Since

\langle \widehat\psi,\phi\rangle =\langle \psi,\widehat\phi\rangle,\quad\text~\psi,\phi\in L^2([-\infty,\infty],\mu)

therefore the linear momentum operator

\widehat{p}

is, in fact, a Hermitian operator. Detailed proofs of this can be found in many textbooks and online (e.g. https://physics.stackexchange.com/a/832341/194354).

Having in hand that the momentum operator is Hermitian, we can prove that the translation operator is a unitary operator. First, it must shown that translation operator is a bounded operator. It is sufficient to state that for all

\psi\inL^2([a,b],\mu)

that

\left\|\left[\widehat{T}_{\mathbf{x}}\psi\right]\!(r)\left\|_ = \right\|\psi(r)\right\|_.

Second, it must be (and can be) shown that

\widehat^\dagger_ \widehat _ =\widehat_ \widehat^\dagger_ =\mathbb.

A detailed proof can be found in reference https://math.stackexchange.com/a/4990451/309209.

Translation Operator operating on a bra

A translation operator

\hat{T}(x)=\intdr~|r+x\rangle\langler|

operating on a bra in the position eigenbasis gives:

\langle \mathbf r| \hat T(\mathbf x) = \langle \mathbf r - \mathbf x|

Splitting a translation into its components

According to the "successive translations" property above, a translation by the vector

x=(x,y,z)

can be written as the product of translations in the component directions:

\hat(\mathbf) = \hat(x\mathbf)\,\hat(y\mathbf)\,\hat(z\mathbf)

where

\hat{x

},\mathbf,\mathbf are unit vectors.

Commutator with position operator

Suppose

|r\rangle

is an eigenvector of the position operator

\hatr

with eigenvalue

. We have

\hat T(\mathbf)\mathbf|\mathbf r\rangle = \hat T(\mathbf)\mathbf|\mathbf r\rangle = \mathbf|\mathbf + \mathbf r\rangle

while

\mathbf\hat T(\mathbf)|\mathbf r\rangle = \hat\mathbf|\mathbf + \mathbf r\rangle = (\mathbf + \mathbf) |\mathbf + \mathbf r\rangle

Therefore, the commutator between a translation operator and the position operator is: $[\mathbf{\hat r},\hat T(\mathbf x)] \equiv \mathbf\hat T(\mathbf x) - \hat T(\mathbf x)\mathbf = \mathbf x \hat T(\mathbf x)$ This can also be written (using the above properties) as: $(\hat T(\mathbf x))^\mathbf\hat T(\mathbf x) = \mathbf + \mathbf x\hat$ where

\hat{I

} is the identity operator.

Commutator with momentum operator

Since translation operators all commute with each other (see above), and since each component of the momentum operator is a sum of two scaled translation operators (e.g.

\hat{p}_y=\lim_\varepsilon

	i\hbar
	\varepsilon

\left(\hat{T}((0,\varepsilon,0))-\hat{T}((0,0,0))\right)

), it follows that translation operators all commute with the momentum operator, i.e.

\hat T(\mathbf) \hat = \hat\hat T(\mathbf)

This commutation with the momentum operator holds true generally even if the system is not isolated where energy or momentum may not be conserved.

Translation group

The set

ak{T}

of translation operators

\hatT(x)

for all

, with the operation of multiplication defined as the result of successive translations (i.e. function composition), satisfies all the axioms of a group:

Closure : When two translations are done consecutively, the result is a single different translation. (See "successive translations" property above.)

is the identity operator, i.e. the operator that has no effect on anything. It functions as the identity element of the group.

Every element has an inverse : As proven above, any translation operator

\hatT(x)

is the inverse of the reverse translation

\hatT(-x)

Associativity : This is the claim that

\hatT(x_1)\left(\hatT(x₂₎\hatT(x_3)\right)=\left(\hatT(x_1)\hatT(x_2)\right)\hatT(x₃₎

. It is true by definition, as is the case for any group based on function composition.

Therefore, the set

ak{T}

of translation operators

\hatT(x)

for all

forms a group.^[3] Since there are continuously infinite number of elements, the translation group is a continuous group. Moreover, the translation operators commute among themselves, i.e. the product of two translation (a translation followed by another) does not depend on their order. Therefore, the translation group is an abelian group.^[4]

The translation group acting on the Hilbert space of position eigenstates is isomorphic to the group of vector additions in the Euclidean space.

Expectation values of position and momentum in the translated state

Consider a single particle in one dimension. Unlike classical mechanics, in quantum mechanics a particle neither has a well-defined position nor a well-defined momentum. In the quantum formulation, the expectation values^[5] play the role of the classical variables. For example, if a particle is in a state

|\psi\rangle

, then the expectation value of the position is

\langle\psi|\hatr|\psi\rangle

, where

\hatr

is the position operator.

If a translation operator

\hatT(x)

acts on the state

|\psi\rangle

, creating a new state

|\psi_2\rangle

then the expectation value of position for

|\psi_2\rangle

is equal to the expectation value of position for

|\psi\rangle

plus the vector

. This result is consistent with what you would expect from an operation that shifts the particle by that amount.

On the other hand, when the translation operator acts on a state, the expectation value of the momentum is not changed. This can be proven in a similar way as the above, but using the fact that translation operators commute with the momentum operator. This result is again consistent with expectations: translating a particle does not change its velocity or mass, so its momentum should not change.

Translational invariance

In quantum mechanics, the Hamiltonian is the operator corresponding to the total energy of a system. For any

|r\rangle

in the domain, let the one vector

|r_{T\rangle\equiv}\hat{T}_x|r\rangle

in the codomain be a newly translated state. If

\langle \mathbf_T|\hat|\mathbf_T\rangle = \langle \mathbf|\hat H|\mathbf\rangle,

then a Hamiltonian is said to be invariant. Since the translation operator is a unitary operator, the antecedent can also be written as

\langle \mathbf|\hat_\mathbf^\hat\hat_\mathbf|\mathbf\rangle = \langle \mathbf|\hat H|\mathbf\rangle.

Since this hold for any

|r\rangle

in the domain, the implication is that

\hat_\mathbf^\hat\hat_\mathbf=\hat

or that

\hat\hat_\mathbf-\hat_\mathbf\hat =[\hat{H},\hat{T}_\mathbf{x}]=0.

Thus, if Hamiltonian commutes with the translation operator, then the Hamiltonian is invariant under translation. Loosely speaking, if we translate the system, then measure its energy, then translate it back, it amounts to the same thing as just measuring its energy directly.

Continuous translational symmetry

See also: Noether's theorem. First we consider the case where all the translation operators are symmetries of the system. Second we consider the case where the translation operator is not a symmetries of the system. As we will see, only in the first case does the conservation of momentum occur.

For example, let

\hat{H}

be the Hamiltonian describing all particles and fields in the universe, and let

\hatT(x)

be the continuous translation operator that shifts all particles and fields in the universe simultaneously by the same amount. If we assert the a priori axiom that this translation is a continuous symmetry of the Hamiltonian (i.e., that

\hat{H}

is independent of location), then, as a consequence, conservation of momentum is universally valid.

On the other hand, perhaps

\hat{H}

and

\hatT(x)

refer to just one particle. Then the translation operators

\hatT(x)

are exact symmetries only if the particle is alone in a vacuum. Correspondingly, the momentum of a single particle is not usually conserved (it changes when the particle bumps into other objects or is otherwise deflected by the potential energy fields of the other particles), but it is conserved if the particle is alone in a vacuum.

Since the Hamiltonian operator commutes with the translation operator when the Hamiltonian is an invariant with respect to translation, therefore $\left[\hat H,\hat T(\mathbf{x})\right]=0\,.$ Further, the Hamiltonian operator also commutes with the infinitesimal translation operator $\begin&\left[\hat H, 1-\frac{i\mathbf{x}\cdot \hat\mathbf{p}}{N\hbar}\right]=0\\& \Rightarrow [\hat H,\hat{\mathbf p}]=0 \\& \Rightarrow \frac\langle\hat\rangle= \frac[\hat H,\hat{\mathbf p}]=0.\end$ In summary, whenever the Hamiltonian for a system remains invariant under continuous translation, then the system has conservation of momentum, meaning that the expectation value of the momentum operator remains constant. This is an example of Noether's theorem.

Discrete translational symmetry

See also: Bloch's theorem. There is another special case where the Hamiltonian may be translationally invariant. This type of translational symmetry is observed whenever the potential is periodic:^[6] $V(r_j\pm a)=V(r_j)$ In general, the Hamiltonian is not invariant under any translation represented by

\hatT_j(x_j)

with

x_j

arbitrary, where

\hatT_j(x_j)

has the property:

\hat T_j(x_j)|r_j\rangle=|r_j+x_j\rangle

and,

(\hat_j(x_j))^\dagger \hat r_j\hat T_j(x_j)=\hat r_j+x_j\hat

(where

\hat{I

} is the identity operator; see proof above).

But, whenever

x_j

coincides with the period of the potential

(\hat_j(a))^\dagger V(\hat r_j)\hat T_j(a)=V(\hat r_j+a\hat)=V(\hat r_j)

Since the kinetic energy part of the Hamiltonian

\hatH

is already invariant under any arbitrary translation, being a function of

\hatp

, the entire Hamiltonian satisfies,

(\hat_j(a))^\dagger \hat H\hat T_j(a)=\hat H

Now, the Hamiltonian commutes with translation operator, i.e. they can be simultaneously diagonalised. Therefore, the Hamiltonian is invariant under such translation (which no longer remains continuous). The translation becomes discrete with the period of the potential.

Discrete translation in periodic potential: Bloch's theorem

See main article: Bloch's theorem. The ions in a perfect crystal are arranged in a regular periodic array. So we are led to the problem of an electron in a potential

V(r)

with the periodicity of the underlying Bravais lattice

V(\mathbf+\mathbf)=V(\mathbf r)

for all Bravais lattice vectors

However, perfect periodicity is an idealisation. Real solids are never absolutely pure, and in the neighbourhood of the impurity atoms the solid is not the same as elsewhere in the crystal. Moreover, the ions are not in fact stationary, but continually undergo thermal vibrations about their equilibrium positions. These destroy the perfect translational symmetry of a crystal. To deal with this type of problems the main problem is artificially divided in two parts: (a) the ideal fictitious perfect crystal, in which the potential is genuinely periodic, and (b) the effects on the properties of a hypothetical perfect crystal of all deviations from perfect periodicity, treated as small perturbations.

Although, the problem of electrons in a solid is in principle a many-electron problem, in independent electron approximation each electron is subjected to the one-electron Schrödinger equation with a periodic potential and is known as Bloch electron^[7] (in contrast to free particles, to which Bloch electrons reduce when the periodic potential is identically zero.)

For each Bravais lattice vector

we define a translation operator

\hatT_R

which, when operating on any function

f(r)

shifts the argument by

\hat T_f(\mathbf r)=f(\mathbf r+\mathbf R)

Since all translations form an Abelian group, the result of applying two successive translations does not depend on the order in which they are applied, i.e.

\hat T_\hat T_=\hat T_\hat T_=\hat T_

In addition, as the Hamiltonian is periodic, we have,

\hat T_\hat H=\hat H\hat T_

Hence, the

\hatT_R

for all Bravais lattice vectors

and the Hamiltonian

\hatH

form a set of commutating operators. Therefore, the eigenstates of

\hatH

can be chosen to be simultaneous eigenstates of all the

\hatT_R

\hat H\psi=\mathcal E\psi

\hat T_\psi=c(\mathbf R)\psi

The eigenvalues

c(R)

of the translation operators are related because of the condition:

\hat T_\hat T_=\hat T_\hat T_=\hat T_

We have,

\begin\hat T_\hat T_\psi & =c(\mathbf R_1)\hat T_\psi\\& =c(\mathbf R_1)c(\mathbf R_2)\psi\end

And,

\hat T_\psi=c(\mathbf R_1+\mathbf R_2)\psi

Therefore, it follows that,

c(\mathbf R_1+\mathbf R_2)=c(\mathbf R_1)c(\mathbf R_2)

Now let the

a_i

's be the three primitive vector for the Bravais lattice. By a suitable choice of

x_i

, we can always write

c(a_i)

in the form

c(\mathbf_i)=e^

is a general Bravais lattice vector, given by

\mathbf R=n_1\mathbf a_1+n_2\mathbf a_2+n_3\mathbf a_3

it follows then,

\beginc(\mathbf R) & =c(n_1\mathbf a_1+n_2\mathbf a_2+n_3\mathbf a_3)\\& =c(n_1\mathbf a_1)c(n_2\mathbf a_2)c(n_3\mathbf a_3)\\& =c(\mathbf a_1)^c(\mathbf a_2)^c(\mathbf a_3)^\end

Substituting

	2\piix_i
c(a
	i)=e

one gets,

\beginc(\mathbf R) & =e^\\& = e^\end

where

k=x₁b₁+x₂b₂+x₃b₃

and the

b_i

's are the reciprocal lattice vectors satisfying the equation

b_{i ⋅ a}_j=2\pi\delta_ij

Therefore, one can choose the simultaneous eigenstates

\psi

of the Hamiltonian

\hatH

and

\hatT_R

so that for every Bravais lattice vector

\begin\psi(\mathbf) & =\hat T_\psi(\mathbf r)\\& = c(\mathbf R)\psi(\mathbf r)\\& =e^\psi(\mathbf r)\end

So,This result is known as Bloch's Theorem.

Time evolution and translational invariance

See main article: article and Time translation symmetry. In the passive transformation picture, translational invariance requires, $[\hat T(\mathbf{x}),\hat H] = 0$ It follows that $[\hat T(\mathbf{x}),\hat U(t)] = 0$ where

\hatU(t)

is the unitary time evolution operator.^[8] When the Hamiltonian is time independent,

\hat U(t)= \exp\left(\frac\right)

If the Hamiltonian is time dependent, the above commutation relation is satisfied if

\hatp

\hatT(x)

commutes with

\hatH(t)

for all t.

Example

Suppose at

t=0

two observers A and B prepare identical systems at

x=0

and

x=a

(fig. 1), respectively. If

|\psi(0)\rangle

be the state vector of the system prepared by A, then the state vector of the system prepared by B will be given by

\hat T(\mathbf)|\psi(0)\rangle

Both the systems look identical to the observers who prepared them. After time

, the state vectors evolve into

\hatU(t)|\psi(0)\rangle

and

\hatU(t)\hatT(a)|\psi(0)\rangle

respectively.Using the above-mentioned commutation relation, the later may be written as,

\hat T(\mathbf)\hat U(t)|\psi(0)\rangle

which is just the translated version of the system prepared by A at time

. Therefore, the two systems, which differed only by a translation at

t=0

, differ only by the same translation at any instant of time. The time evolution of both the systems appear the same to the observers who prepared them. It can be concluded that the translational invariance of Hamiltonian implies that the same experiment repeated at two different places will give the same result (as seen by the local observers).

Notes and References

http://bohr.physics.berkeley.edu/classes/221/1112/notes/spatialdof.pdf Lecture notes by Robert Littlejohn
Web site: Mulders . P.J. . Advanced Quantum Mechanics . Vrije Universiteit Amsterdam . 22 March 2022.
Page-816, Chapter-17, Mathematical Methods for Physicists, Seventh Edition, by Arfken, Weber and Harris
Page-47, Chapter-1, Modern Quantum Mechanics, Second edition, J.J. Sakurai, Jim J. Napolitano
P. 127, Section 4.2, R. Shankar, Principles of Quantum Mechanics
Chapter-8, Solid State Physics by Neil W. Ashcroft and N. David Mermin
P-133, Chapter-8, Solid State Physics by Neil W. Ashcroft and N. David Mermin
P. 308, Chapter 3, Volume 1, Claude Cohen-Tannoudji, Bernard Diu, Franck Laloë