On effective constructions of existentially closed groups

I Scott

Published 2024-04-17Version 1

Existentially closed groups are, informally, groups that contain solutions to every consistent finite system of equations and inequations. They were introduced in 1951 in an algebraic context and subsequent research elucidated deep connections with group theory and computability theory. We continue this investigation, with particular emphasis on illuminating the relationship with computability theory. In particular, we show that existentially closed groups can be built at the level of the halting problem and that this is optimal. Moreover, using the the theory of the enumeration degrees and some work of Martin Ziegler in computable group theory, we show that the previous result relativises in a somewhat subtle way. We then tease apart the complexity contributed by ``global'' and ``local'' structure, showing that the finitely generated subgroups have complexity at the level of the PA degrees. Finally, we investigate the computability-theoretic complexity of omitting the non-principal quantifier-free types from a list of types, from which we obtain an upper bound on the complexity of building two existentially closed groups that are ``as different as possible''.