γ-space

In mathematics, a $\gamma$ -space is a topological space that satisfies a certain a basic selection principle. An infinite cover of a topological space is an $\omega$ -cover if every finite subset of this space is contained in some member of the cover, and the whole space is not a member the cover. A cover of a topological space is a $\gamma$ -cover if every point of this space belongs to all but finitely many members of this cover. A $\gamma$ -space is a space in which every open $\omega$ -cover contains a $\gamma$ -cover.

History edit

Gerlits and Nagy introduced the notion of γ-spaces.^[1] They listed some topological properties and enumerated them by Greek letters. The above property was the third one on this list, and therefore it is called the γ-property.

Characterizations edit

Combinatorial characterization edit

Let $[\mathbb {N} ]^{\infty }$ be the set of all infinite subsets of the set of natural numbers. A set $A\subset [\mathbb {N} ]^{\infty }$ is centered if the intersection of finitely many elements of $A$ is infinite. Every set $a\in [\mathbb {N} ]^{\infty }$ we identify with its increasing enumeration, and thus the set $a$ we can treat as a member of the Baire space $\mathbb {N} ^{\mathbb {N} }$ . Therefore, $[\mathbb {N} ]^{\infty }$ is a topological space as a subspace of the Baire space $\mathbb {N} ^{\mathbb {N} }$ . A zero-dimensional separable metric space is a γ-space if and only if every continuous image of that space into the space $[\mathbb {N} ]^{\infty }$ that is centered has a pseudointersection.^[2]

Topological game characterization edit

Let $X$ be a topological space. The $\gamma$ -has a pseudo intersection if there is a set game played on $X$ is a game with two players Alice and Bob.

1st round: Alice chooses an open $\omega$ -cover ${\mathcal {U}}_{1}$ of $X$ . Bob chooses a set $U_{1}\in {\mathcal {U}}_{1}$ .

2nd round: Alice chooses an open $\omega$ -cover ${\mathcal {U}}_{2}$ of $X$ . Bob chooses a set $U_{2}\in {\mathcal {U}}_{2}$ .

etc.

If $\{U_{n}:n\in \mathbb {N} \}$ is a $\gamma$ -cover of the space $X$ , then Bob wins the game. Otherwise, Alice wins.

A player has a winning strategy if he knows how to play in order to win the game (formally, a winning strategy is a function).

A topological space is a $\gamma$ -space iff Alice has no winning strategy in the $\gamma$ -game played on this space.^[1]

Properties edit

A topological space is a γ-space if and only if it satisfies ${\text{S}}_{1}(\Omega ,\Gamma )$ selection principle.^[1]
Every Lindelöf space of cardinality less than the pseudointersection number ${\mathfrak {p}}$ is a $\gamma$ -space.
Every $\gamma$ -space is a Rothberger space,^[3] and thus it has strong measure zero.

Let $X$ be a Tychonoff space, and $C(X)$ be the space of continuous functions $f\colon X\to \mathbb {R}$ with pointwise convergence topology. The space $X$ is a $\gamma$ -space if and only if $C(X)$ is Fréchet–Urysohn if and only if $C(X)$ is strong Fréchet–Urysohn.^[1]
Let $A$ be a ${\binom {\mathbf {\Omega } }{\mathbf {\Gamma } }}$ subset of the real line, and $M$ be a meager subset of the real line. Then the set $A+M=\{a+x:a\in A,x\in M\}$ is meager.^[4]