| dc.description.abstract | The drainage of a non-Newtonian film entrapped between two fluid particles that are moving toward one another with time-dependent velocities, causing either coalescence and rebound, is examined in this thesis. Attention is given to the non-Newtonian rheology of the continuous phase where particles disperse, in order to better understand how particles coalesce and rebound, which is important in a variety of natural processes and industrial applications. It is specifically anticipated that the non-Newtonian continuous phase will adhere to the power law model. The interfaces are permitted to deform during drainage. Non-Newtonian flows are formed when materials are processed by procedures like coating, soap solutions, or polymer extrusion. | |
