Baire space explained

X

is said to be a Baire space if countable unions of closed sets with empty interior also have empty interior.According to the Baire category theorem, compact Hausdorff spaces and complete metric spaces are examples of Baire spaces.The Baire category theorem combined with the properties of Baire spaces has numerous applications in topology, geometry, and analysis, in particular functional analysis.[1] [2] For more motivation and applications, see the article Baire category theorem. The current article focuses more on characterizations and basic properties of Baire spaces per se.

\Rn

in his 1899 thesis.[3]

Definition

The definition that follows is based on the notions of meagre (or first category) set (namely, a set that is a countable union of sets whose closure has empty interior) and nonmeagre (or second category) set (namely, a set that is not meagre). See the corresponding article for details.

A topological space

X

is called a Baire space if it satisfies any of the following equivalent conditions:
  1. Every countable intersection of dense open sets is dense.
  2. Every countable union of closed sets with empty interior has empty interior.
  3. Every meagre set has empty interior.
  4. Every nonempty open set is nonmeagre.[4]
  5. Every comeagre set is dense.
  6. Whenever a countable union of closed sets has an interior point, at least one of the closed sets has an interior point.

The equivalence between these definitions is based on the associated properties of complementary subsets of

X

(that is, of a set

A\subseteqX

and of its complement

X\setminusA

) as given in the table below.
Property of a set Property of complement
open closed
comeagre meagre
dense has empty interior
has dense interior nowhere dense

Baire category theorem

See main article: Baire category theorem. The Baire category theorem gives sufficient conditions for a topological space to be a Baire space.

BCT1 shows that the following are Baire spaces:

\R

of real numbers.

BCT2 shows that the following are Baire spaces:

One should note however that there are plenty of spaces that are Baire spaces without satisfying the conditions of the Baire category theorem, as shown in the Examples section below.

Properties

Given a sequence of continuous functions

fn:X\toY

with pointwise limit

f:X\toY.

If

X

is a Baire space then the points where

f

is not continuous is in

X

and the set of points where

f

is continuous is dense in

X.

A special case of this is the uniform boundedness principle.

Examples

\R

of real numbers with the usual topology is a Baire space.

\Q

of rational numbers (with the topology induced from

\R

) is not a Baire space, since it is meagre.

\R

) is a Baire space, since it is comeagre in

\R.

X=[0,1]\cup([2,3]\cap\Q)

(with the topology induced from

\R

) is nonmeagre, but not Baire. There are several ways to see it is not Baire: for example because the subset

[0,1]

is comeagre but not dense; or because the nonempty subset

[2,3]\cap\Q

is open and meagre.

X=\{1\}\cup([2,3]\cap\Q)

is not Baire. It is nonmeagre since

1

is an isolated point.

The following are examples of Baire spaces for which the Baire category theorem does not apply, because these spaces are not locally compact and not completely metrizable:

\R2

consisting of the open upper half plane together with the rationals on the -axis, namely,

X=(\R x (0,infty))\cup(\Q x \{0\}),

is a Baire space,[11] because the open upper half plane is dense in

X

and completely metrizable, hence Baire. The space

X

is not locally compact and not completely metrizable. The set

\Q x \{0\}

is closed in

X

, but is not a Baire space. Since in a metric space closed sets are Gδ sets, this also shows that in general Gδ sets in a Baire space need not be Baire.

Algebraic varieties with the Zariski topology are Baire spaces. An example is the affine space

An

consisting of the set

Cn

of -tuples of complex numbers, together with the topology whose closed sets are the vanishing sets of polynomials

f\inC[x1,\ldots,xn].

References

External links

Notes and References

  1. Web site: Your favourite application of the Baire Category Theorem . Mathematics Stack Exchange.
  2. Web site: Classic applications of Baire category theorem . MathOverflow . en.
  3. Baire. R.. Sur les fonctions de variables réelles. Annali di Matematica Pura ed Applicata. 1899. 3. 1–123.
  4. As explained in the meagre set article, for an open set, being nonmeagre in the whole space is equivalent to being nonmeagre in itself.
  5. Web site: Ma . Dan . A Question About The Rational Numbers . Dan Ma's Topology Blog . en . 3 June 2012. Theorem 3
  6. Oxtoby . J. . Cartesian products of Baire spaces . . 1961 . 49 . 2 . 157–166 . 10.4064/fm-49-2-157-166 .
  7. Fleissner . W. . Kunen . K. . Barely Baire spaces . Fundamenta Mathematicae . 1978 . 101 . 3 . 229–240 . 10.4064/fm-101-3-229-240 .
  8. Web site: Intersection of two open dense sets is dense . Mathematics Stack Exchange.
  9. Web site: The Sorgenfrey line is a Baire Space . Mathematics Stack Exchange .
  10. Web site: The Sorgenfrey plane and the Niemytzki plane are Baire spaces . Mathematics Stack Exchange .
  11. Web site: Example of a Baire metric space which is not completely metrizable . Mathematics Stack Exchange .