Stability analysis of transitional flows based on disturbance magnitude (2507.05036v1)

Abstract: We utilize input-output analysis and the small gain theorem to derive a disturbance-based criterion for analyzing the stability of flows. A detailed study is conducted on applying this criterion to three canonical flows: Couette, plane Poiseuille, and Blasius flows, considering three input-output approaches: unstructured, structured with non-repeated blocks, and structured with repeated blocks. By covering a wide range of Reynolds numbers for each flow, we reveal a complex interplay between dominant flow structures that determine the stability threshold bound, arising from both unstructured and structured input-output approaches. The obtained thresholds comply with a hierarchical relationship derived from our theoretical analysis, in which the unstructured approach provides a stricter bound, i.e., a lower threshold on disturbance magnitude to trigger instability, compared to structured approaches. The latter are accounting (to some extent) for the flow system nonlinearity. This threshold can be triggered through various transition routes, such as the presence of a finite-size perturbation in the flow or via a transient growth scenario. We demonstrate that our analysis converges to linear stability theory when an infinitesimally small threshold is imposed. Our stability analysis is more general, allowing for finite-amplitude perturbations and nonlinear interactions, which enables us to explain the observed transition in various shear flows at both subcritical and supercritical Reynolds numbers, as observed in experimental and direct numerical simulation studies. In particular, we utilize our stability criterion to demonstrate that Couette flow can become unstable and transition can be triggered at different Reynolds numbers, which is consistent with past experimental observations.