Chaotic Dynamics of Conformable Semigroups via Classical Theory

Abstract

Conformable derivatives involve a fractional parameter while preserving locality: on smooth functions they reduce to a classical derivative multiplied by an explicit weight. Exploiting this structural feature, we show that conformable time evolution does not give rise to a genuinely new semigroup theory. Rather, it can be fully interpreted as a classical C0--semigroup observed through a nonlinear change of time. For δ∈(0,1], we introduce the conformable clock \[ (t)=tδδ, \] and prove that every C0--δ--semigroup Sδ admits the representation \[ Sδ(t)= T((t)), \] where T is a uniquely determined classical C0--semigroup on the same state space. This correspondence is exact at the infinitesimal level: the δ--generator of Sδ coincides with the generator of T on a common domain, and conformable mild solutions are in one-to-one correspondence with classical mild solutions under the reparametrization s=(t). In particular, orbit sets are unchanged by the conformable clock, so orbit-based linear dynamical properties are invariant; δ--hypercyclicity and δ--chaos coincide with their classical counterparts. As an application, we derive a conformable version of the Desch--Schappacher--Webb chaos criterion by transporting the classical result. The analysis is carried out in conformable Lebesgue spaces Lp,δ, which are shown to be isometrically equivalent to standard Lp spaces, allowing a direct transfer of estimates and spectral arguments. Altogether, the results clarify which dynamical features of conformable models are intrinsic and which arise solely from a nonlinear change of time.