In mathematics, the Segal–Bargmann space (for Irving Segal and Valentine Bargmann), also known as the Bargmann space or Bargmann–Fock space, is the space of holomorphic functions F in n complex variables satisfying the square-integrability condition:
\|F\|2:=\pi-n
| \int | |
| \Complexn |
|F(z)|2\exp(-|z|2)dz<infty,
where here dz denotes the 2n-dimensional Lebesgue measure on
\Complexn.
\langleF\midG\rangle=\pi-n
| \int | |
| \Complexn |
\overline{F(z)}G(z)\exp(-|z|2)dz.
The space was introduced in the mathematical physics literature separately by Bargmann and Segal in the early 1960s; see and . Basic information about the material in this section may be found in and . Segal worked from the beginning in the infinite-dimensional setting; see and Section 10 of for more information on this aspect of the subject.
A basic property of this space is that pointwise evaluation is continuous, meaning that for each
a\in\Complexn,
|F(a)|<C\|F\|.
It then follows from the Riesz representation theorem that there exists a unique Fa in the Segal–Bargmann space such that
F(a)=\langleFa\midF\rangle.
The function Fa may be computed explicitly as
Fa(z)=\exp(\overline{a} ⋅ z)
where, explicitly,
\overline{a} ⋅ z=
| n | |
| \sum | |
| j=1 |
\overline{aj}zj.
The function Fa is called the coherent state (applied in mathematical physics) with parameter a, and the function
\kappa(a,z):=\overline{Fa(z)}
is known as the reproducing kernel for the Segal–Bargmann space. Note that
F(a)=\langleFa\midF\rangle=\pi-n
| \int | |
| \Complexn |
\kappa(a,z)F(z)\exp(-|z|2)dz,
meaning that integration against the reproducing kernel simply gives back (i.e., reproduces) the function F, provided, of course that F is an element of the space (and in particular is holomorphic).
Note that
| 2 | |
| \|F | |
| a\| |
=\langleFa\midFa\rangle=Fa(a)=\exp(|a|2).
It follows from the Cauchy–Schwarz inequality that elements of the Segal–Bargmann space satisfy the pointwise bounds
|F(a)|\leq\|Fa\|\|F\|=\exp(|a|2/2)\|F\|.
One may interpret a unit vector in the Segal–Bargmann space as the wave function for a quantum particle moving in
\Rn.
\Complexn
\Rn
Given a unit vector F in the Segal–Bargmann space, the quantity
\pi-n|F(z)|2\exp(-|z|2)
may be interpreted as a sort of phase space probability density for the particle. Since the above quantity is manifestly non-negative, it cannot coincide with the Wigner function of the particle, which usually has some negative values. In fact, the above density coincides with the Husimi function of the particle, which is obtained from the Wigner function by smearing with a Gaussian. This connection will be made more precise below, after we introduce the Segal–Bargmann transform.
One may introduce annihilation operators
aj
| * | |
| a | |
| j |
aj=\partial/\partialzj
and
| * | |
| a | |
| j |
=zj
These operators satisfy the same relations as the usual creation and annihilation operators, namely, the
aj
| * | |
| a | |
| j |
\left[aj,a
| * | |
| k |
\right]=\deltaj,k
Furthermore, the adjoint of
aj
| *. | |
| a | |
| j |
aj
| * | |
| a | |
| j |
We may now construct self-adjoint "position" and "momentum" operators Aj and Bj by the formulas:
Aj=(aj+a
| *)/\sqrt | |
| j |
2
Bj=(aj-
| *)/(i\sqrt | |
| a | |
| j |
2)
These operators satisfy the ordinary canonical commutation relations, and it can be shown that that they act irreducibly on the Segal–Bargmann space; see Section 14.4 of .
Since the operators and from the previous section satisfy the Weyl relations and act irreducibly on the Segal–Bargmann space, the Stone–von Neumann theorem applies. Thus, there is a unitary map from the position Hilbert space
L2(\Rn)
The map may be computed explicitly as a modified double Weierstrass transform,
(Bf)(z)=
| \int | |
| \Rn |
\exp[-(z ⋅ z-2\sqrt{2}z ⋅ x+x ⋅ x)/2]f(x)dx,
where dx is the n-dimensional Lebesgue measure on
\Rn
\Complexn.
We may now be more precise about the connection between the Segal–Bargmann space and the Husimi function of a particle. If is a unit vector in
L2(\Rn),
\Complexn
\pi-n|(Bf)(z)|2\exp(-|z|2)~.
The claim is then that the above density is the Husimi function of, which may be obtained from the Wigner function of by convolving with a double Gaussian (the Weierstrass transform). This fact is easily verified by using the formula for along with the standard formula for the Husimi function in terms of coherent states.
Since is unitary, its Hermitian adjoint is its inverse. Recalling that the measure on
\Complexn
| -|z|2 | |
| e |
dz
f(x)=
| \int | |
| \Complexn |
\exp[-(\overline{z} ⋅ \overline{z}-2\sqrt{2}\overline{z} ⋅ x+x ⋅ x)/2](Bf)(z)
| -|z|2 | |
| e |
dz.
Since, however, is a holomorphic function, there can be many integrals involving that give the same value. (Think of the Cauchy integral formula.) Thus, there can be many different inversion formulas for the Segal–Bargmann transform .
Another useful inversion formula is[1]
f(x)=C\exp(-|x|2/2)
| \int | |
| \Rn |
(Bf)(x+iy)\exp(-|y|2/2)dy,
where
C=\pi-n/4(2\pi)-n/2.
This inversion formula may be understood as saying that the position "wave function" may be obtained from the phase-space "wave function" by integrating out the momentum variables. This is to be contrasted to the Wigner function, where the position probability density is obtained from the phase space (quasi-)probability density by integrating out the momentum variables.
There are various generalizations of the Segal–Bargmann space and transform. In one of these,[2] [3] the role of the configuration space
\Rn
\Complexn
\operatorname{SL}(N,\Complex)
This generalized Segal–Bargmann transform gives rise to a system of coherent states, known as heat kernel coherent states. These have been used widely in the literature on loop quantum gravity.