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We give Scott sentences for certain computable groups, and we use index set calculations as a way of checking that our Scott sentences are as simple as possible. We consider finitely generated groups and torsion-free abelian groups of finite rank. For both kinds of groups, the computable ones all have computable $Sigma_3$ Scott sentences. Sometimes we can do better. In fact, the computable finitely generated groups that we have studied all have Scott sentences that are computable $d$-$Sigma_2$ (the conjunction of a computable $Sigma_2$ sentence and a computable $Pi_2$ sentence). This was already shown for the finitely generated free groups. Here we show it for all finitely generated abelian groups, and for the infinite dihedral group. Among the computable torsion-free abelian groups of finite rank, we focus on those of rank $1$. These are exactly the additive subgroups of $mathbb{Q}$. We show that for some of these groups, the computable $Sigma_3$ Scott sentence is best possible, while for others, there is a computable $d$-$Sigma_2$ Scott sentence.
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The Hanf number for a set $S$ of sentences in $L_{omega_1,omega}$ (or some other logic) is the least infinite cardinal $kappa$ such that for all $varphiin S$, if $varphi$ has models in all infinite cardinalities less than $kappa$, then it has models of all infinite cardinalities. S-D. Friedman asked what is the Hanf number for Scott sentences of computable structures. We show that the value is $beth_{omega_1^{CK}}$. The same argument proves that $beth_{omega_1^{CK}}$ is the Hanf number for Scott sentences of hyperarithmetical structures.
Given a countable scattered linear order $L$ of Hausdorff rank $alpha < omega_1$ we show that it has a $dtext{-}Sigma_{2alpha+1}$ Scott sentence. Ash calculated the back and forth relations for all countable well-orders. From this result we obtain that this upper bound is tight, i.e., for every $alpha < omega_1$ there is a linear order whose optimal Scott sentence has this complexity. We further show that for all countable $alpha$ the class of Hausdorff rank $alpha$ linear orders is $pmb Sigma_{2alpha+2}$ complete.
We prove that for every Scott set $S$ there are $S$-saturated real closed fields and models of Presburger arithmetic.
Classical scope-assignment strategies for multi-quantifier sentences involve quantifier phrase (QP)-movement. More recent continuation-based approaches provide a compelling alternative, for they interpret QPs in situ - without resorting to Logical Forms or any structures beyond the overt syntax. The continuation-based strategies can be divided into two groups: those that locate the source of scope-ambiguity in the rules of semantic composition and those that attribute it to the lexical entries for the quantifier words. In this paper, we focus on the former operation-based approaches and the nature of the semantic operations involved. More specifically, we discuss three such possible operation-based strategies for multi-quantifier sentences, together with their relative merits and costs.
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