The stable and unstable manifolds associated with a saddle point in two-dimensional non-areapreserving flows under general time-aperiodic perturbations are examined. An improvement to existing geometric Melnikov theory on the normal displacement of these manifolds is presented. A new theory on the previously neglected tangential displacement is developed. Together, these enable locating the perturbed invariant manifolds to leading order. An easily usable Laplace transform expression for the location of the perturbed time-dependent saddle is also obtained. The theory is illustrated with an application to the Duffing equation. 1. Introduction. Invariant manifolds are important entities in continuous dynamical systems, forming crucial flow organizers. Their movement under perturbations can alter the global flow structure. The original results of Melnikov [40] relate to the normal displacement of stable and unstable manifolds in a homoclinic structure in two-dimensional area-preserving flow, under a time-sinusoidal perturbation. The transverse zeroes of the so-called Melnikov function identify when the perturbed invariant manifolds intersect, leading to chaos via the Smale-Birkhoff theorem [26, 4, 57]. Extensions of the Melnikov method to higher dimensions [25, 44, 60, 54], time-aperiodicity and/or finite-time [41, 44, 58, 62, 8], subharmonic bifurcations [40, 57, 61, 59], nonhyperbolicity [54, 60, 63], and non-area-preservation [32] are available.While Melnikov methods can be used to determine how invariant manifolds move normal to the original manifolds, there has been no method in the literature in which the tangential movement is characterized. This study addresses this issue, arriving at a Melnikov-like function for the tangential displacement, under general time-dependent perturbations. The original two-dimensional flow is assumed to contain a saddle structure but need not be areapreserving. The displacement is expressed as a function of the original position p on the manifold and the time-slice t. Along the way, a similar quantification for the normal displacement is obtained, in which potential divergence issues in the Melnikov function and the legitimacy of ignoring higher-order terms are explicitly addressed. The normal and tangential results together permit the locating of the perturbed stable and unstable manifolds of the
