This thesis is concerned with the expansions of algebraic structures and their fit in Shelah’s classification landscape.
The first part deals with the expansion of a theory by a random predicate for a substructure model of a reduct of the theory. Let T be a theory in a language
$\mathcal {L}$
. Let
$T_0$
be a reduct of T. Let
$\mathcal {L}_S = \mathcal {L}\cup \{S\}$
, for S a new unary predicate symbol, and
$T_S$
be the
$\mathcal {L}_S$
-theory that axiomatises the following structures:
$(\mathscr {M},\mathscr {M}_0)$
consist of a model
$\mathscr {M}$
of T and S is a predicate for a model
$\mathscr {M}_0$
of
$T_0$
which is a substructure of
$\mathscr {M}$
. We present a setting for the existence of a model-companion
$TS$
of
$T_S$
. As a consequence, we obtain the existence of the model-companion of the following theories, for
$p>0$
a prime number:
From an independence relation
in
T, we define independence relations in
$TS$
and identify which properties of
are transferred to those new independence relations in
$TS$
, and under which conditions. This allows us to exhibit hypotheses under which the expansion from
T to
$TS$
preserves
$\mathrm {NSOP}_{1}$
, simplicity, or stability. In particular, under some technical hypothesis on
T, we may draw the following picture (the left column implies the right column):
Configuration
$T_0\subseteq T$
| Generic expansion
$TS$
|
---|
$T_0 = T$
| Preserves stability |
$T_0\subseteq T$
| Preserves
$\mathrm {NSOP}_{1}$
|
$T_0 = \emptyset $
| Preserves simplicity |
In particular, this construction produces new examples of
$\mathrm {NSOP}_{1}$
not simple theories, and we study in depth a particular example: the expansion of an algebraically closed field of positive characteristic by a generic additive subgroup. We give a full description of imaginaries, forking, and Kim-forking in this example.
The second part studies expansions of the group of integers by p-adic valuations. We prove quantifier elimination in a natural language and compute the dp-rank of these expansions: it equals the number of independent p-adic valuations considered. Thus, the expansion of the integers by one p-adic valuation is a new dp-minimal expansion of the group of integers. Finally, we prove that the latter expansion does not admit intermediate structures: any definable set in the expansion is either definable in the group structure or is able to “reconstruct” the valuation using only the group operation.
Abstract prepared by Christian d’Elbée.
E-mail: [email protected]
URL: https://choum.net/~chris/page_perso