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We introduce a generalization of sequential compactness using barriers on $\omega $ extending naturally the notion introduced in [W. Kubiś and P. Szeptycki, On a topological Ramsey theorem, Canad. Math. Bull., 66 (2023), 156–165]. We improve results from [C. Corral and O. Guzmán and C. López-Callejas, High dimensional sequential compactness, Fund. Math.] by building spaces that are ${\mathcal {B}}$-sequentially compact but not ${\mathcal {C}}$-sequentially compact when the barriers ${\mathcal {B}}$ and ${\mathcal {C}}$ satisfy certain rank assumption which turns out to be equivalent to a Katětov-order assumption. Such examples are constructed under the assumption ${\mathfrak {b}} ={\mathfrak {c}}$. We also exhibit some classes of spaces that are ${\mathcal {B}}$-sequentially compact for every barrier ${\mathcal {B}}$, including some classical classes of compact spaces from functional analysis, and as a byproduct, we obtain some results on angelic spaces. Finally, we introduce and compute some cardinal invariants naturally associated to barriers.
Let
$\mathcal {I}$
be an ideal on
$\omega $
. For
$f,\,g\in \omega ^{\omega }$
we write
$f \leq _{\mathcal {I}} g$
if
$f(n) \leq g(n)$
for all
$n\in \omega \setminus A$
with some
$A\in \mathcal {I}$
. Moreover, we denote
$\mathcal {D}_{\mathcal {I}}=\{f\in \omega ^{\omega }: f^{-1}[\{n\}]\in \mathcal {I} \text { for every } n\in \omega \}$
(in particular,
$\mathcal {D}_{\mathrm {Fin}}$
denotes the family of all finite-to-one functions).
We examine cardinal numbers
$\mathfrak {b}(\geq _{\mathcal {I}}\cap (\mathcal {D}_{\mathcal {I}} \times \mathcal {D}_{\mathcal {I}}))$
and
$\mathfrak {b}(\geq _{\mathcal {I}}\cap (\mathcal {D}_{\mathrm {Fin}}\times \mathcal {D}_{\mathrm {Fin}}))$
describing the smallest sizes of unbounded from below with respect to the order
$\leq _{\mathcal {I}}$
sets in
$\mathcal {D}_{\mathrm {Fin}}$
and
$\mathcal {D}_{\mathcal {I}}$
, respectively. For a maximal ideal
$\mathcal {I}$
, these cardinals were investigated by M. Canjar in connection with coinitial and cofinal subsets of the ultrapowers.
We show that
$\mathfrak {b}(\geq _{\mathcal {I}}\cap (\mathcal {D}_{\mathrm {Fin}} \times \mathcal {D}_{\mathrm {Fin}})) =\mathfrak {b}$
for all ideals
$\mathcal {I}$
with the Baire property and that
$\aleph _1 \leq \mathfrak {b}(\geq _{\mathcal {I}}\cap (\mathcal {D}_{\mathcal {I}} \times \mathcal {D}_{\mathcal {I}})) \leq \mathfrak {b}$
for all coanalytic weak P-ideals (this class contains all
$\bf {\Pi ^0_4}$
ideals). What is more, we give examples of Borel (even
$\bf {\Sigma ^0_2}$
) ideals
$\mathcal {I}$
with
$\mathfrak {b}(\geq _{\mathcal {I}}\cap (\mathcal {D}_{\mathcal {I}} \times \mathcal {D}_{\mathcal {I}}))=\mathfrak {b}$
as well as with
$\mathfrak {b}(\geq _{\mathcal {I}}\cap (\mathcal {D}_{\mathcal {I}} \times \mathcal {D}_{\mathcal {I}})) =\aleph _1$
.
We also study cardinals
$\mathfrak {b}(\geq _{\mathcal {I}}\cap (\mathcal {D}_{\mathcal {J}} \times \mathcal {D}_{\mathcal {K}}))$
describing the smallest sizes of sets in
$\mathcal {D}_{\mathcal {K}}$
not bounded from below with respect to the preorder
$\leq _{\mathcal {I}}$
by any member of
$\mathcal {D}_{\mathcal {J}}\!$
. Our research is partially motivated by the study of ideal-QN-spaces: those cardinals describe the smallest size of a space which is not ideal-QN.
In this paper we investigate the structure of uncountable maximal antichains of Silver forcing and show that they have to be at least of size d, where d is the dominating number. Part of this work can be used to show that the additivity of the Silver forcing ideal has size at least the unbounding number b. It follows that every reasonable amoeba Silver forcing adds a dominating real.
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