Nuclear space explained

In mathematics, nuclear spaces are topological vector spaces that can be viewed as a generalization of finite-dimensional Euclidean spaces and share many of their desirable properties. Nuclear spaces are however quite different from Hilbert spaces, another generalization of finite-dimensional Euclidean spaces. They were introduced by Alexander Grothendieck.

The topology on nuclear spaces can be defined by a family of seminorms whose unit balls decrease rapidly in size. Vector spaces whose elements are "smooth" in some sense tend to be nuclear spaces; a typical example of a nuclear space is the set of smooth functions on a compact manifold. All finite-dimensional vector spaces are nuclear. There are no Banach spaces that are nuclear, except for the finite-dimensional ones. In practice a sort of converse to this is often true: if a "naturally occurring" topological vector space is a Banach space, then there is a good chance that it is nuclear.

Original motivation: The Schwartz kernel theorem

See also: Schwartz kernel theorem. Much of the theory of nuclear spaces was developed by Alexander Grothendieck while investigating the Schwartz kernel theorem and published in . We now describe this motivation.

For any open subsets

\Omega₁\subseteq\R^m

and

\Omega₂\subseteq\R^n,

the canonical map

l{D}^\prime\left(\Omega₁ x \Omega_2\right)\toL_b\left(C

	infty

	c

\left(\Omega_2\right);l{D}^\prime\left(\Omega_{1\right)\right)}

is an isomorphism of TVSs (where

L_b\left(C

	infty\left(\Omega

	2\right);

l{D}^\prime\left(\Omega_{1\right)\right)}

has the topology of uniform convergence on bounded subsets) and furthermore, both of these spaces are canonically TVS-isomorphic to

l{D}^\prime\left(\Omega_1\right)n{\widehat{ ⊗ }}l{D}^\prime\left(\Omega_2\right)

(where since

l{D}^\prime\left(\Omega_1\right)

is nuclear, this tensor product is simultaneously the injective tensor product and projective tensor product). In short, the Schwartz kernel theorem states that:

\mathcal^\left(\Omega_1 \times \Omega_2\right) \cong \mathcal^\left(\Omega_1\right) \mathbin \mathcal^\left(\Omega_2\right) \cong L_b\left(C_c^\left(\Omega_2\right); \mathcal^\left(\Omega_1\right)\right)

where all of these TVS-isomorphisms are canonical.

This result is false if one replaces the space

	infty
C
	c

with

L²

(which is a reflexive space that is even isomorphic to its own strong dual space) and replaces

l{D}^\prime

with the dual of this

L²

space. Why does such a nice result hold for the space of distributions and test functions but not for the Hilbert space

L²

(which is generally considered one of the "nicest" TVSs)? This question led Grothendieck to discover nuclear spaces, nuclear maps, and the injective tensor product.

Motivations from geometry

Another set of motivating examples comes directly from geometry and smooth manifold theory^[1] ^{appendix 2}. Given smooth manifolds

M,N

and a locally convex Hausdorff topological vector space, then there are the following isomorphisms of nuclear spaces

C^infty(M) ⊗ C^infty(N)\congC^infty(M x N)

C^infty(M) ⊗ F\cong\{f:M\toF:fissmooth\}

Definition

This section lists some of the more common definitions of a nuclear space. The definitions below are all equivalent. Note that some authors use a more restrictive definition of a nuclear space, by adding the condition that the space should also be a Fréchet space. (This means that the space is complete and the topology is given by a family of seminorms.)

The following definition was used by Grothendieck to define nuclear spaces.

Definition 0: Let

be a locally convex topological vector space. Then

is nuclear if for every locally convex space

the canonical vector space embedding

X ⊗ _\piY\to

	\prime
l{B}
	\sigma,

	\prime
Y
	\sigma

\right)

is an embedding of TVSs whose image is dense in the codomain (where the domain

X ⊗ _\piY

is the projective tensor product and the codomain is the space of all separately continuous bilinear forms on

	\prime
X
	\sigma

	\prime
Y
	\sigma

endowed with the topology of uniform convergence on equicontinuous subsets).

has a topology that is defined by some family of seminorms. For every seminorm, the unit ball is a closed convex symmetric neighborhood of the origin, and conversely every closed convex symmetric neighborhood of 0 is the unit ball of some seminorm. (For complex vector spaces, the condition "symmetric" should be replaced by "balanced".) If

is a seminorm on

then

X_p

denotes the Banach space given by completing the auxiliary normed space using the seminorm

There is a natural map

X\toX_p

(not necessarily injective).

is another seminorm, larger than

(pointwise as a function on

), then there is a natural map from

X_q

X_p

such that the first map factors as

X\toX_q\toX_p.

These maps are always continuous. The space

is nuclear when a stronger condition holds, namely that these maps are nuclear operators. The condition of being a nuclear operator is subtle, and more details are available in the corresponding article.

Definition 1: A nuclear space is a locally convex topological vector space such that for every seminorm

we can find a larger seminorm

so that the natural map

X_q\toX_p

is nuclear.

Informally, this means that whenever we are given the unit ball of some seminorm, we can find a "much smaller" unit ball of another seminorm inside it, or that every neighborhood of 0 contains a "much smaller" neighborhood. It is not necessary to check this condition for all seminorms

; it is sufficient to check it for a set of seminorms that generate the topology, in other words, a set of seminorms that are a subbase for the topology.

Instead of using arbitrary Banach spaces and nuclear operators, we can give a definition in terms of Hilbert spaces and trace class operators, which are easier to understand. (On Hilbert spaces nuclear operators are often called trace class operators.)We will say that a seminorm

is a Hilbert seminorm if

X_p

is a Hilbert space, or equivalently if

comes from a sesquilinear positive semidefinite form on

Definition 2: A nuclear space is a topological vector space with a topology defined by a family of Hilbert seminorms, such that for every Hilbert seminorm

we can find a larger Hilbert seminorm

so that the natural map from

X_q

X_p

is trace class.

Some authors prefer to use Hilbert–Schmidt operators rather than trace class operators. This makes little difference, because every trace class operator is Hilbert–Schmidt, and the product of two Hilbert–Schmidt operators is of trace class.

Definition 3: A nuclear space is a topological vector space with a topology defined by a family of Hilbert seminorms, such that for every Hilbert seminorm

we can find a larger Hilbert seminorm

so that the natural map from

X_q

X_p

is Hilbert–Schmidt.

If we are willing to use the concept of a nuclear operator from an arbitrary locally convex topological vector space to a Banach space, we can give shorter definitions as follows:

Definition 4: A nuclear space is a locally convex topological vector space such that for every seminorm

the natural map from

X\toX_p

is nuclear.

Definition 5: A nuclear space is a locally convex topological vector space such that every continuous linear map to a Banach space is nuclear.

Grothendieck used a definition similar to the following one:

Definition 6: A nuclear space is a locally convex topological vector space

such that for every locally convex topological vector space

the natural map from the projective to the injective tensor product of

and

is an isomorphism.

In fact it is sufficient to check this just for Banach spaces

or even just for the single Banach space

\ell¹

of absolutely convergent series.

Characterizations

Let

be a Hausdorff locally convex space. Then the following are equivalent:

is nuclear;

for any locally convex space

the canonical vector space embedding

X ⊗ _\piY\tol{B}_\epsilon\left(

	\prime
X
	\sigma

	\prime
Y
	\sigma

\right)

is an embedding of TVSs whose image is dense in the codomain;

the canonical vector space embedding

X\widehat{ ⊗ }_\piY\toX\widehat{ ⊗ }_\epsilonY

is a surjective isomorphism of TVSs;

for any locally convex Hausdorff space

the canonical vector space embedding

X\widehat{ ⊗ }_\piY\toX\widehat{ ⊗ }_\epsilonY

is a surjective isomorphism of TVSs;

the canonical embedding of

\ell^1[\N,X]

\ell^1(\N,X)

is a surjective isomorphism of TVSs;

the canonical map of

\ell¹\widehat{ ⊗ }_\piX\to\ell¹\widehat{ ⊗ }_\epsilonX

is a surjective TVS-isomorphism.

for any seminorm

we can find a larger seminorm

so that the natural map

X_q\toX_p

is nuclear;

for any seminorm

we can find a larger seminorm

so that the canonical injection

	\prime
X
	p

\to

	\prime
X
	q

is nuclear;

the topology of

is defined by a family of Hilbert seminorms, such that for any Hilbert seminorm

we can find a larger Hilbert seminorm

so that the natural map

X_q\toX_p

is trace class;

has a topology defined by a family of Hilbert seminorms, such that for any Hilbert seminorm

we can find a larger Hilbert seminorm

so that the natural map

X_q\toX_p

is Hilbert–Schmidt;

for any seminorm

the natural map from

X\toX_p

is nuclear.

any continuous linear map to a Banach space is nuclear;
every continuous seminorm on

is prenuclear;

every equicontinuous subset of

X^\prime

is prenuclear;

every linear map from a Banach space into

X^\prime

that transforms the unit ball into an equicontinuous set, is nuclear;

the completion of

is a nuclear space;

is a Fréchet space then the following are equivalent:

is nuclear;

every summable sequence in

is absolutely summable;

the strong dual of

is nuclear;

Sufficient conditions

A locally convex Hausdorff space is nuclear if and only if its completion is nuclear.
Every subspace of a nuclear space is nuclear.
Every Hausdorff quotient space of a nuclear space is nuclear.
The inductive limit of a countable sequence of nuclear spaces is nuclear.
The locally convex direct sum of a countable sequence of nuclear spaces is nuclear.
The strong dual of a nuclear Fréchet space is nuclear.
- In general, the strong dual of a nuclear space may fail to be nuclear.
A Fréchet space whose strong dual is nuclear is itself nuclear.
The limit of a family of nuclear spaces is nuclear.
The product of a family of nuclear spaces is nuclear.
The completion of a nuclear space is nuclear (and in fact a space is nuclear if and only if its completion is nuclear).
The tensor product of two nuclear spaces is nuclear.
The projective tensor product, as well as its completion, of two nuclear spaces is nuclear.

Suppose that

X,Y,

and

are locally convex space with

is nuclear.

is nuclear then the vector space of continuous linear maps

L_\sigma(X,N)

endowed with the topology of simple convergence is a nuclear space.

is a semi-reflexive space whose strong dual is nuclear and if

is nuclear then the vector space of continuous linear maps

L_b(X,N)

(endowed with the topology of uniform convergence on bounded subsets of

) is a nuclear space.

Examples

is a set of any cardinality, then

\R^d

and

\Complex^d

(with the product topology) are both nuclear spaces.

A relatively simple infinite-dimensional example of a nuclear space is the space of all rapidly decreasing sequences

c=\left(c_1,c_2,\ldots\right).

("Rapidly decreasing" means that

c_np(n)

is bounded for any polynomial

). For each real number

it is possible to define a norm

\| ⋅ \|_s

\|c\|_s = \sup_ \left|c_n\right| n^s

If the completion in this norm is

C_s,

then there is a natural map from

C_s\toC_t

whenever

s\geqt,

and this is nuclear whenever

s>t+1

essentially because the series

\sumn^t

is then absolutely convergent. In particular for each norm

\| ⋅ \|_t

this is possible to find another norm, say

\| ⋅ \|_t,

such that the map

C_t+2\toC_t

is nuclear. So the space is nuclear.

The space of smooth functions on any compact manifold is nuclear.
The Schwartz space of smooth functions on

\Rⁿ

for which the derivatives of all orders are rapidly decreasing is a nuclear space.

The space of entire holomorphic functions on the complex plane is nuclear.

l{D}^\prime,

the strong dual of

l{D},

is nuclear.

Properties

Nuclear spaces are in many ways similar to finite-dimensional spaces and have many of their good properties.

Every finite-dimensional Hausdorff space is nuclear.
A Fréchet space is nuclear if and only if its strong dual is nuclear.
Every bounded subset of a nuclear space is precompact (recall that a set is precompact if its closure in the completion of the space is compact). This is analogous to the Heine-Borel theorem. In contrast, no infinite-dimensional normed space has this property (although the finite-dimensional spaces do).
If

is a quasi-complete (i.e. all closed and bounded subsets are complete) nuclear space then

has the Heine-Borel property.

A nuclear quasi-complete barrelled space is a Montel space.
Every closed equicontinuous subset of the dual of a nuclear space is a compact metrizable set (for the strong dual topology).
Every nuclear space is a subspace of a product of Hilbert spaces.
Every nuclear space admits a basis of seminorms consisting of Hilbert norms.
Every nuclear space is a Schwartz space.
Every nuclear space possesses the approximation property.
Any subspace and any quotient space by a closed subspace of a nuclear space is nuclear.
If

is nuclear and

is any locally convex topological vector space, then the natural map from the projective tensor product of A and

to the injective tensor product is an isomorphism. Roughly speaking this means that there is only one sensible way to define the tensor product. This property characterizes nuclear spaces

In the theory of measures on topological vector spaces, a basic theorem states that any continuous cylinder set measure on the dual of a nuclear Fréchet space automatically extends to a Radon measure. This is useful because it is often easy to construct cylinder set measures on topological vector spaces, but these are not good enough for most applications unless they are Radon measures (for example, they are not even countably additive in general).

The kernel theorem

Much of the theory of nuclear spaces was developed by Alexander Grothendieck while investigating the Schwartz kernel theorem and published in . We have the following generalization of the theorem.

Schwartz kernel theorem: Suppose that

is nuclear,

is locally convex, and

is a continuous bilinear form on

X x Y.

Then

originates from a space of the form

	\prime
X
	A^\prime

\widehat{ ⊗ }_\epsilon

	\prime
Y
	B^\prime

where

A^\prime

and

B^\prime

are suitable equicontinuous subsets of

X^\prime

and

Y^\prime.

Equivalently,

is of the form,

v(x, y) = \sum_^ \lambda_i \left\langle x, x_i^ \right\rangle \left\langle y, y_i^ \right\rangle \quad \text (x, y) \in X \times Y

where

\left(λ_i\right)\in\ell¹

and each of

\left\{

	\prime
x
	1,

	\prime
x
	2,

\ldots\right\}

and

\left\{

	\prime
y
	1,

	\prime
y
	2,

\ldots\right\}

are equicontinuous. Furthermore, these sequences can be taken to be null sequences (that is, convergent to 0) in

	\prime
X
	A^\prime

and

	\prime
Y
	B^\prime

respectively.

Bochner–Minlos theorem

See also: Bochner's theorem. Any continuous positive-definite functional

on a nuclear space

is called a characteristic functional if

C(0)=1,

and for any

z_j\inC,

x_j\inA

and

j,k=1,\ldots,n,

\sum_^n \sum_^n z_j \bar z_k C(x_j - x_k) \geq 0.

Given a characteristic functional on a nuclear space

the Bochner–Minlos theorem (after Salomon Bochner and Robert Adol'fovich Minlos) guarantees the existence and uniqueness of a corresponding probability measure

\mu

on the dual space

A^\prime

such that

C(y) = \int_ e^ \, d\mu(x),

where

C(y)

is the Fourier transform of

\mu

, thereby extending the inverse Fourier transform to nuclear spaces.^[2]

In particular, if

is the nuclear space

A = \bigcap_^\infty H_k,

where

H_k

are Hilbert spaces, the Bochner–Minlos theorem guarantees the existence of a probability measure with the characteristic function

	2
\\|y\\|
	H₀

that is, the existence of the Gaussian measure on the dual space. Such measure is called white noise measure. When

is the Schwartz space, the corresponding random element is a random distribution.

Strongly nuclear spaces

A strongly nuclear space is a locally convex topological vector space such that for any seminorm

there exists a larger seminorm

so that the natural map

X_q\toX_p

is a strongly nuclear.

Bibliography

Book: Becnel, Jeremy. Tools for Infinite Dimensional Analysis. CRC Press. 2021. 978-0-367-54366-2. 1195816154 .
Grothendieck. Alexandre. Grothendieck. Produits tensoriels topologiques et espaces nucléaires. 1955 . Memoirs of the American Mathematical Society. 16 .
Book: Diestel, Joe. The metric theory of tensor products : Grothendieck's résumé revisited. American Mathematical Society. Providence, R.I. 2008. 978-0-8218-4440-3. 185095773 .
Book: Dubinsky, Ed. The structure of nuclear Fréchet spaces. Springer-Verlag. Berlin New York. 1979. 3-540-09504-7. 5126156 .
Book: Grothendieck, Grothendieck. Produits tensoriels topologiques et espaces nucléaires. American Mathematical Society. Providence. 1966. 0-8218-1216-5. 1315788. fr .
- - Book: Holden, Helge . Øksendal . Bernt . Ubøe . Jan . Zhang . Tusheng . Stochastic Partial Differential Equations . Springer Science & Business Media . London New York . 2009 . 978-0-387-89488-1.
Book: Husain, Taqdir. Barrelledness in topological and ordered vector spaces. Springer-Verlag. Berlin New York. 1978. 3-540-09096-7. 4493665 .
- Book: Gel'fand. I. M.. N. Ya. . Vilenkin. Generalized Functions – vol. 4: Applications of harmonic analysis. 1964 . New York . Academic Press . 310816279 .
Takeyuki Hida and Si Si, Lectures on white noise functionals, World Scientific Publishing, 2008.
- - Book: Pietsch. Albrecht. Nuclear locally convex spaces. 1965. Springer-Verlag. Berlin, New York. Ergebnisse der Mathematik und ihrer Grenzgebiete. 978-0-387-05644-9. 1972. 66. 0350360 .
Book: Pietsch, Albrecht. Nuclear locally convex spaces. Springer-Verlag. Berlin, New York. 1972. 0-387-05644-0. 539541 .
Book: Robertson, A.P. . W.J. Robertson . Topological vector spaces . Cambridge Tracts in Mathematics . 53 . 1964 . Cambridge University Press. 141.
Book: Robertson, A. P.. Topological vector spaces. University Press. Cambridge England. 1973. 0-521-29882-2. 589250 .
Book: Ryan, Raymond. Introduction to tensor products of Banach spaces. Springer. London New York. 2002. 1-85233-437-1. 48092184 .
- Book: Simon, Barry . Functional Integration and Quantum Physics . American Mathematical Soc. . Providence, R.I . 2005 . 978-0-8218-3582-1 . ocm56894469.
- Book: Wong. Schwartz spaces, nuclear spaces, and tensor products. Springer-Verlag. Berlin New York. 1979. 3-540-09513-6. 5126158 .

Notes and References

Book: Costello, Kevin . Renormalization and effective field theory. 2011. American Mathematical Society. 978-0-8218-5288-0. Providence, R.I.. 692084741.
T. R. Johansen, The Bochner-Minlos Theorem for nuclear spaces and an abstract white noise space, 2003.