# Indestructibility of the tree property

**Authors:** Radek Honzik, Sarka Stejskalova

arXiv: 1907.03142 · 2020-04-22

## TL;DR

This paper proves the indestructibility of the tree property at certain cardinals under specific forcing notions, with applications to Prikry-type forcing and generalized invariants, using Mitchell and Cohen forcings.

## Contribution

It establishes the indestructibility of the tree property at successors of regular cardinals under broad classes of forcing, extending previous results with new models and forcing techniques.

## Key findings

- Tree property is indestructible under all +-cc forcing in certain models.
- Results apply to Prikry-type forcing and generalized cardinal invariants.
- Constructs models where the tree property persists under various forcing notions.

## Abstract

In the first part of the paper, we show that if $\omega \le \kappa < \lambda$ are cardinals, $\kappa^{<\kappa} = \kappa$, and $\lambda$ is weakly compact, then in $V[\M(\kappa,\lambda)]$ the tree property at $\lambda = \kappa^{++V[\M(\kappa,\lambda)]}$ is indestructible under all $\kappa^+$-cc forcing notions which live in $V[\Add(\kappa,\lambda)]$, where $\Add(\kappa,\lambda)$ is the Cohen forcing for adding $\lambda$-many subsets of $\kappa$ and $\M(\kappa,\lambda)$ is the standard Mitchell forcing for obtaining the tree property at $\lambda = (\kappa^{++})^{V[\M(\kappa,\lambda)]}$. This result has direct applications to Prikry-type forcing notions and generalized cardinal invariants. In the second part, we assume that $\lambda$ is supercompact and generalize the construction and obtain a model $V^*$, a generic extension of $V$, in which the tree property at $(\kappa^{++})^{V^*}$ is indestructible under all $\kappa^+$-cc forcing notions living in $V[\Add(\kappa,\lambda)]$, and in addition by all forcing notions living in $V^*$ which are $\kappa^+$-closed and ``liftable'' in a prescribed sense (such as $\kappa^{++}$-directed closed forcings or well-met forcings which are $\kappa^{++}$-closed with the greatest lower bounds).

## Full text

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## References

23 references — full list in the complete paper: https://tomesphere.com/paper/1907.03142/full.md

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Source: https://tomesphere.com/paper/1907.03142