Practical trainings, student assistants and theses
|Offer||All | School practical training | Master theses | Research Assistant | Student practical training | Volunteer internship | Diploma theses | Bachelor theses | Student Assistant ||
|Institute/ Dep.||All | FKVF | FKVP | FSSL | FWD | FWDC | FWDF | | FWF | FWGA-X | FWGP-I | FWIO-N | FWIZ | FWPB | FWPL | FWPR | FWU | FWUM|
Experimental investigation of influence of interfacial viscoelasticity on the dripping to jetting transition (Id 333)
School practical training / Student practical training / Bachelor theses / Master theses / Compulsory internship
Liquid jets are unstable and eventually form droplets to minimize the surface energy with the surrounding fluid. The transition from dripping to jetting and dynamics of the droplet pinch-off have been studied extensively for various systems, from pure Newtonian fluids to complex non-Newtonian liquids. The jetting process has received significant attention as it is a critical step in various three-dimensional (3D) printing techniques such as dropwise additive manufacturing and the direct ink writing method. In most of the applications surface active materials such as surfactants, nanoparticles, and polymers exist in the systems. The presence of surface-active materials reduces the liquid-fluid surface energies and in some cases generates a viscoelastic layer at the interface.
In this research, we aim to study the influence of interfacial viscoelasticity on the dripping to jetting transition. The study is conducted by the injection of an aqueous phase (nanoparticle dispersions) into an oil phase that contains surfactants over a wide range of flow rates. We tune the magnitude of interfacial viscoelasticity by changing the concentration of surfactants and nanoparticles.
Does the dripping to jetting transition (critical flow rate) linearly increase by increasing the interfacial viscoelasticity?
1. Measurements of interfacial tension and surface elasticity for a range of particle and surfactant concentration using Profile analysis tensiometry, and Langmuir trough.
2. Dripping to jetting experiments for the selected systems using high-speed cameras and in-house setups.
Department: Transport processes at interfaces
- Field of study: chemical engineering, process engineering, fluid mechanics, or similar focus in chemistry or physics
- Experience with laboratory work and imaging measurement techniques is beneficial
- Working in an international team
- Duration: at least 6 months
- Location: Dresden-Rossendorf