{ "id": "2310.19799", "version": "v1", "published": "2023-07-13T10:11:11.000Z", "updated": "2023-07-13T10:11:11.000Z", "title": "Direct Numerical Simulation for Parametric Vertical Vibration and Atomization of Sessile Drops", "authors": [ "Debashis Panda" ], "comment": "MSc Thesis at Imperial College London", "categories": [ "physics.flu-dyn" ], "abstract": "Sessile drop vertical vibrations and atomization is commonly analyzed by simpler unconstrained instabilities like Faraday waves and hence, detailed studies of the phenomenon are still an open question to the fluid dynamics community. We address two critical gaps using direct numerical simulation, i.e., (i) the cause of subharmonic response of azimuthal waves, and (ii) the dependence of vertical vibrations to the universal pinchoff regime in the atomization. First, a high mode excitation of a large drop of 100 microliters is implemented. It is found that the subharmonic response is not via Faraday waves, rather it is the harmonics of the interfacial waves that induce azimuthal waves near the contact line. An analogous self-inducing dynamical system is formalized between the tip and near the contact line to elucidate the mechanism. Second, a low mode excitation of small drop of 30 microliter is used to critically explain the cause of primary pinch-off via crater formation and secondary pinch-off via ligament retraction. The pinch-off test in both cases revealed that the primary pinch-off is in visco-capillary scaling regime, while the secondary pinch-off is affected by the inertial forces via oscillatory body forces of vibration.", "revisions": [ { "version": "v1", "updated": "2023-07-13T10:11:11.000Z" } ], "analyses": { "keywords": [ "direct numerical simulation", "parametric vertical vibration", "sessile drop", "atomization", "secondary pinch-off" ], "tags": [ "dissertation" ], "note": { "typesetting": "TeX", "pages": 0, "language": "en", "license": "arXiv", "status": "editable" } } }