Nucleus (order theory)

In mathematics, and especially in order theory, a nucleus is a function $F$ on a meet-semilattice ${\mathfrak {A}}$ such that (for every $p$ in ${\mathfrak {A}}$ ):^[1]

$p\leq F(p)$
$F(F(p))=F(p)$
$F(p\wedge q)=F(p)\wedge F(q)$

Every nucleus is evidently a monotone function.

Frames and locales

Usually, the term nucleus is used in frames and locales theory (when the semilattice ${\mathfrak {A}}$ is a frame).

Proposition: If $F$ is a nucleus on a frame ${\mathfrak {A}}$ , then the poset $\operatorname {Fix} (F)$ of fixed points of $F$ , with order inherited from ${\mathfrak {A}}$ , is also a frame.^[2]

References

^ Johnstone, Peter (1982), Stone Spaces, Cambridge University Press, p. 48, ISBN 978-0-521-33779-3, Zbl 0499.54001
^ Miraglia, Francisco (2006). An Introduction to Partially Ordered Structures and Sheaves. Polimetrica s.a.s. Theorem 13.2, p. 130. ISBN 9788876990359.

[1] Johnstone, Peter (1982), Stone Spaces, Cambridge University Press, p. 48, ISBN 978-0-521-33779-3, Zbl 0499.54001

[2] Miraglia, Francisco (2006). An Introduction to Partially Ordered Structures and Sheaves. Polimetrica s.a.s. Theorem 13.2, p. 130. ISBN 9788876990359.

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