Regular Orbits and Periodic Loops in Multiply Barred Galactic Potentials

Abstract

We show that nonchaotic multiply periodic particle orbits can exist in a galaxy-like potential where a small, fast-tumbling nuclear bar is nested inside a main bar that has a slower pattern speed. We introduce the concept of a loop: a one-dimensional curve such that particles distributed along it at some initial instant return to the same curve (as viewed in the rotating frame of one of the bars) after the bars return to the same relative position. Just as particles following regular orbits in a simply barred potential are trapped around closed periodic orbits, so regular orbits in a doubly barred potential oscillate about stable loops. We find both loops that remain aligned with the inner bar and loops aligned with the outer bar: particles trapped around these loops could form the building blocks for a long-lived, self-consistent, doubly barred galaxy. In a realistic doubly barred galaxy potential, we demonstrate the existence of stable loops that support the structure of the inner bar. We use the epicyclic approximation to preview the pattern of gas flow in a doubly barred potential.