This image shows Kathrin Schulte (geb. Eisenschmidt)

Kathrin Schulte (geb. Eisenschmidt)

Dr.-Ing.

Habilitation candidate
Institute of Aerospace Thermodynamics

Contact

+49 711 685 62334
+49 711 685 62317

Pfaffenwaldring 31
70569 Stuttgart
Deutschland
Room: 1-144

Subject

Droplet dynamics: Numerical, analytical and experimental investigation of drop collisions, drop-wall interactions and phase transitions

Research networks:

SFB Transregio 75 "SFB TRR75" (Managing director and sub-project manager)

EXC 2075 Cluster of Excellence "Data-Integrated Simulation Science (SimTech)" (Participating Researcher, Teilprojektleiterin) https://www.simtech.uni-stuttgart.de

Fellow in the Margarete von Wrangell habilitation program

  1. Potyka, J., Kromer, J., Liu, M., Schulte, K., & Bothe, D. (2022). Modelling and~Numerical Simulation of~Binary Droplet Collisions Under Extreme Conditions. In Fluid Mechanics and Its Applications (pp. 127--147). Springer International Publishing. https://doi.org/10.1007/978-3-031-09008-0_7
  2. Weigand, B., Schulte, K., & Tropea, C. (2021). Selected Results of the Collaborative Research Center “Droplet Dynamics under Extreme Ambient Conditions” SFB-TRR 75. International Conference on Liquid Atomization and Spray Systems (ICLASS).
  3. Schulte, K., Weigand, B., & Tropea, C. (2020). Selected results of the collaborative research center “Droplet dynamics under extreme ambient conditions” SFB-TRR 75. ICLASS 2018 - 14th International Conference on Liquid Atomization and Spray Systems.
  4. Schulte, K., Weigand, B., & Tropea, C. (2019). Selected Results of the Collaborative Research Center" Droplet Dynamics under Extreme Ambient Conditions" SFB-TRR 75. Ilass Europe. 29th European Conference on Liquid Atomization and Spray Systems.
  5. Schulte, K., & Weigand, B. (2018). On the analytical modelling of the initial ice growth in a supercooled liquid droplet. International Journal of Heat and Mass Transfer, 127, 1070–1081.
  6. Karch, G. K., Beck, F., Ertl, M., Meister, C., Schulte, K., Weigand, B., Ertl, T., & Sadlo, F. (2018). Visual Analysis of Inclusion Dynamics in Two-Phase Flow. IEEE Transactions on Visualization and Computer Graphics, 24(5), Article 5.
  7. Schulte, K. (n.d.). Modelling of the Initial Ice Growth in a Supercooled Liquid Droplet (p. Online-Ressource, 141 Seiten) [HOCHSCHULSCHRIFT]. Verlag Dr. Hut.
  8. Tropea, C., Weigand, B., & Schulte, K. (2017). Selected Results of the Collaborative Research Center" Droplet Dynamics under Extreme Ambient Conditions" SFB/TRR 75. Ilass Europe. 28th European Conference on Liquid Atomization and Spray Systems, 296--303.
  9. Dragomirescu, F. I., Eisenschmidt, K., Rohde, C., & Weigand, B. (2016). Perturbation solutions for the finite radially symmetric Stefan problem. International Journal of Thermal Sciences, 104, 386–395.
  10. Eisenschmidt, K., Ertl, M., Gomaa, H., Kieffer-Roth, C., Meister, C., Rauschenberger, P., Reitzle, M., Schlottke, K., & Weigand, B. (2016). Direct numerical simulations for multiphase flows: An overview of the multiphase code FS3D. Applied Mathematics and Computation, 272, 508–517.
  11. Karch, G. K., Sadlo, F., Meister, C., Rauschenberger, P., Eisenschmidt, K., Weigand, B., & Ertl, T. (2013). Visualization of piecewise linear interface calculation. IEEE Pacific Visualization Symposium, 121–128.
  12. Rauschenberger, P., Criscione, A., Eisenschmidt, K., Kintea, D., Jakirli?, S., Tukovi?, ?, Roisman, I. V., Weigand, B., & Tropea, C. (2013). Comparative assessment of Volume-of-Fluid and Level-Set methods by relevance to dendritic ice growth in supercooled water. Computers and Fluids, 79, 44–52.
  13. Weigand, B., & Eisenschmidt, K. (2012). The extended Graetz problem with piecewise constant wall temperature for laminar and turbulent flows through a concentric annulus. International Journal of Thermal Sciences, 54, 89–97.
  14. Rauschenberger, P., Schlottke, J., Eisenschmidt, K., & Weigand, B. (2011). Direct numerical simulation of multiphase flow with rigid body motion in an Eulerian framework. ILASS-Europe 2011, 24th European Conference on Liquid Atomization and Spray Systems.
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