5.1. First Definition
Let us consider a unital associative algebra with generators
obeying canonical commutation relations (CCR):
(Weyl algebra).
Here, f and g are elements of real vector space E equipped with non-degenerate antisymmetric inner product , generators depend linearly on f. We assume that Weyl algebra is complex algebra equipped with an antilinear involution and that generators are self-adjoint with respect to this involution.
Let us fix a representation of the Weyl algebra (representation of canonical commutation relations) in Hilbert space
. We assume that generators are represented by self-adjoint operators
; hence we can consider unitary operators
. It is easy to check that
These relations are formally equivalent to (
35). We consider the smallest linear subspace of the space of bounded linear operators in
containing all operators
; the closure of this space in norm-topology is a
-algebra that can be regarded as an exponential form of Weyl algebra (see, for example, [
14] and references therein for the mathematical theory of Weyl algebra). We will work with this algebra denoted by
The space of continuous linear functionals on
will be denoted by
Notice that a functional
is determined by its values on operators
, therefore we can consider
L as a non-linear functional
on
E (the representation of states of Weyl algebra by means of non-linear functionals was rediscovered and studied in [
14]).
In particular, positive functionals on the algebra (quantum states) can be represented by non-linear functionals; we will use the term L-functional for non-linear functionals representing states. (Recall that a linear functional L on *-algebra is positive if for every )
If we have a normalized vector
or, more generally, a density matrix
K in representation space of some *-algebra
we can obtain a quantum state
by the formulas
where
stands for the operator representing an element
Every quantum state can be represented by a vector in some representation of *-algebra (Gelfand-Naimark-Segal construction).
If
is the Weyl algebra
we represent a density matrix
K in any representation of canonical commutation relations (= in any representation of
) by L-functional
One can say that L-functionals describe states in all representations of canonical commutation relations.
The evolution operators of quantum theory constitute a one-parameter group of automorphisms of the algebra
generated by an infinitesimal automorphism
They induce evolution operators acting on quantum states; these operators can be extended to
. To find evolution operators one should solve the equation of motion (
1). We apply the methods of preceding sections assuming that
We define covariant symbols of operators acting in
using systems of vectors
and vectors
that are defined in the following way. We assume that
,
. It follows that
To get a function
R obeying (
25) we can take
where the constant
C is chosen in such a way that
Here
is a measure on
or at least a rule that allows us to calculate integrals of some functions defined on this space (in (
39) we need only integrals of quadratic exponents).
In what follows we assume that the antisymmetric inner product is represented in the form
and
; then
We assume that
by changing the measure
Then in the notations of
Section 2 we have
Let us suppose that the evolution is specified by an infinitesimal automorphism of Weyl algebra
represented as a commutator
H of the element of
with
. Here
is a self-adjoint element of
:
where
(Notice that one can consider also a more general case when
is a formal expression such that the commutator with
makes sense.)
It is easy to check that the covariant symbol of the operator
H has the form
Using (
9) we obtain a representation of the symbol of the evolution operator in
in terms of functional integrals
where we integrate over the set of functions obeying conditions
.
The evolution operator
in the algebra
is dual to the evolution operator
in the space
of linear functionals on
hence the operator
K entering the equation of motion for
L-functionals is dual to the infinitesimal automorphism
H. Using the formula (
29) we can say the symbol of
K coincides with the symbol of
H and the symbols of operators of evolution
and
coincide. This remark allows us to say that
the symbol of the operator of evolution in the formalism of L-functionals is expressed in terms of functional integrals by the formula (
42).
The same statement can be obtained from the equation of motion in the formalism of L-functionals. The time derivative of
can be written in the form
hence
We can write (
43) In the form in the form
where
Here
It is easy to check that the symbol of the operator
K is given by the formula (
41). We obtain another derivation of the functional integral (
42) for the evolution operator in the formalism of
L-functionals.
Sometimes it is convenient to introduce the Planck constant
ℏ in the formula (
43) assuming that in the defining relations of Weyl algebra we have
ℏ in the right-hand side:
where
and replacing
with
Then
It follows from (
44) that the equation of motion for
L-functionals has a limit as
5.2. Second Definition
Let us consider another form of canonical commutation relations:
where
is a non-degenerate pairing between vector space
and complex conjugate vector space
. (Here
.) We will assume that this paring is defined on
E; then it is linear with respect to the first argument and antilinear with respect to the second argument.(Notice that in our notations
E and
consist of the same elements but have different complex structures). Then (
45) can be represented takes the form
(The involution
transforms
into
We assume that
is linear with respect to
f, then
is antilinear with respect to
.) We do not assume that the pairing
is well-defined for all pairs
; in particular,
can be infinite).
If the space
consists of functions on measure space
then
should be regarded as generalized functions:
Then canonical commutation relations (
45) can be written in the form
If
k is a discrete parameter (i.e.,
is a discrete set with counting measure) the above relations can be written as follows
The relations (
45) are obviously equivalent to the relations (
35) (to get (
35) from (
45) we can consider self-adjoint elements
).
The relations (
45) are especially convenient in the case of an infinite number of degrees of freedom. In this situation one should use the original definition of L-functional (see [
11,
12,
13]).
Again we can write canonical commutation relations in exponential form introducing expressions
Notice that is not holomorphic with respect to therefore it would be more appropriate to use the notation as we are doing in similar situations below.
Notice that in the case when is finite coincides with up to a finite constant factor. However, we do not assume that (This is important for applications to string theory).
We define vector space
as a space of linear combinations of expressions of the form
where
and
belongs to some class of polynomials with respect to
The relations (
45), (
48) specify multiplication in
, but this multiplication is not always defined. Nevertheless one can consider
as a version of Weyl algebra. (Better to say that our construction gives various versions of Weyl algebra because we did not specify the class of polynomials and topology in
). We fix some topology in
in such a way that
is infinitely differentiable with respect to
Then the elements
are dense in
(diffrentiating
we obtain polynomials of
). This means that a continuous linear functional
L on
is specified by non-linear functional
(by values of
L on
The space of of continuous linear functionals on
is denoted by
Notice that we can say that
where
stands for the standard pairing between
and
We say that non-linear functionals corresponding to quantum states (to positive functionals =elements of obeying ) are L-functionals.
We represent a density matrix
K in any representation of canonical commutation relations (
45), (
48) by L-functional
Every element specifies two operators acting in the space of linear functionals The first operator transforms the functional into the functional Applying this construction to the cases and we obtain operators denoted by and . The second operator transforms the functional into the functional ; if we start with we get operators denoted by .
The evolution operators of quantum theory constitute a one-parameter group of automorphisms of generated by an infinitesimal automorphism They induce evolution operators acting on and transforming quantum states to quantum states.
Let us suppose that the evolution is specified by an infinitesimal automorphism of Weyl algebra
represented as a commutator
H of the element of
with
. Here
is a self-adjoint element of
or a self-adjoint formal expression
such that the commutator
H is a well-defined derivation of
that can be regarded as an infinitesimal automorphism (i.e. solving the equations of motion we obtain a one-parameter group of evolution operators
). This allows us to write an equation of motion (
1) in the space
taking
where
We solve the equation of motion (
1) applying the methods of
Section 2 and assuming that
We define covariant symbols of operators acting in
using systems of vectors
and vectors
that are defined in the following way. We assume that
corresponds to a non-linear functional
and that
. It follows that
To get a function
R obeying (
25) we take
where the constant
C is chosen in such a way that the formula (
39) is satisfied.
It is easy to calculate the covariant symbol of the operator
This allows us to get a representation of the symbol of the evolution operator in terms of functional integrals
In particular, if
is a quadratic translation-invariant Hamiltonian we obtain
Here We can consider also a more general case when where s is a discrete index and
Let us consider a general translation-invariant Hamiltonian (
49). In other words, we assume that the integrand in (
49) contains delta-function
(the arguments
are points of
plus discrete indices).
We represent as a sum of the quadratic part and perturbation Then we can consider time-dependent Hamiltonian where For this means that we switch on the interaction adiabatically. If denotes the evolution operator for the corresponding “Hamiltonian” and stands for a translation-invariant stationary state of quadratic “Hamiltonian” . Then is a translation-invariant stationary state of the “Hamiltonian”
In the derivation of the formula (
50) we assumed that the “Hamiltonian”
H does not depend on time but this formula can be applied also to time-dependent “Hamiltonians”. This remark allows us to express
in terms of functional integrals. If we start with an equilibrium state
the state
is also an equilibrium state (in general with different temperature), however, the above considerations can be applied also in non-equilibrium situations. They can be considered as justification of Keldysh formalism in non-equilibrium statistical physics and lead to the same Feynman diagrams. (See [
12] for another derivation of Keldysh diagram techniques in the formalism of L-functionals.)
The above formulas were written in the assumption that
In general we should include the factor
ℏ into the right-hand side of the formula (
45) and into the left-hand side of the equation of motion (
1).
Itf we represent elements of
by non-linear functionals
the operators
,
can be represented in the form
where
are operators of multiplication by
for
and by
for
, and
are derivatives taken, respectively, with respect to
and
. (To simplify notations we assumed that
E consists of functions on discrete space
; points of
are labeled by index
k).
It is easy to derive from these formulas that the equations of motion for functionals have a limit as ℏ tends to zero.