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Main Authors: Gonzalez, David, Knight, Julia
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.04404
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author Gonzalez, David
Knight, Julia
author_facet Gonzalez, David
Knight, Julia
contents Friedman and Stanley developed the notion of Borel reducibility and illustrated its use in comparing classification problems for some familiar classes of countable structures. For many embeddings, the fact that the embedding is $1-1$ on isomorphism types is explained by the existence of simple formulas that, uniformly, interpret the input structure in the output structure. For the embeddings of graphs in trees, and in linear orderings, there is no uniform interpretation. We focus on a version of the Friedman-Stanley embedding introduced by Harrison-Trainor and Montalban that takes each structure $A$ for the language of graphs to a labeled tree $T_A$. Gonzalez and Rossegger showed that this embedding preserves Scott complexity. We refine this result, showing that for an $X$-computable ordinal, if one of $A$, $T_A$ has a computable infinitary Scott sentence, then so does the other, and the complexities match. Let $\mathbb{T}$ be the class of labeled trees isomorphic to those in the range of the embedding, and let $\mathbb{T}^α$ be the subclass consisting of structures of Scott rank at most $α$. It follows from results of Gao that $\mathbb{T}$ is not Borel. We show that for each $α$, $\mathbb{T}^α$ is Borel. In fact, if $α$ is an $X$-computable ordinal, then $\mathbb{T}^α$ is complete $X$-effective $Π_{2α+2}$.
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Computable Scott Sentences and the Friedman-Stanley embedding
Gonzalez, David
Knight, Julia
Logic
Friedman and Stanley developed the notion of Borel reducibility and illustrated its use in comparing classification problems for some familiar classes of countable structures. For many embeddings, the fact that the embedding is $1-1$ on isomorphism types is explained by the existence of simple formulas that, uniformly, interpret the input structure in the output structure. For the embeddings of graphs in trees, and in linear orderings, there is no uniform interpretation. We focus on a version of the Friedman-Stanley embedding introduced by Harrison-Trainor and Montalban that takes each structure $A$ for the language of graphs to a labeled tree $T_A$. Gonzalez and Rossegger showed that this embedding preserves Scott complexity. We refine this result, showing that for an $X$-computable ordinal, if one of $A$, $T_A$ has a computable infinitary Scott sentence, then so does the other, and the complexities match. Let $\mathbb{T}$ be the class of labeled trees isomorphic to those in the range of the embedding, and let $\mathbb{T}^α$ be the subclass consisting of structures of Scott rank at most $α$. It follows from results of Gao that $\mathbb{T}$ is not Borel. We show that for each $α$, $\mathbb{T}^α$ is Borel. In fact, if $α$ is an $X$-computable ordinal, then $\mathbb{T}^α$ is complete $X$-effective $Π_{2α+2}$.
title Computable Scott Sentences and the Friedman-Stanley embedding
topic Logic
url https://arxiv.org/abs/2605.04404