Dr.-Ing. Ahmed Hassan
Hamburg University of Technology (TUHH)
Institute for Fluid Dynamics and Ship Theory (M8)
Am Schwarzenberg-Campus 4 (C)
D-21073 Hamburg
Room C5.014
Phone: +49 40 42878 4849
E-mail:ahmed.hassan(at)tuhh(dot)de
URL: http://www.tuhh.de/fds/staff/
Bio-Sketch
2011 - 2016
B.Sc., Aerospace engineering, Cairo university, Egypt
2016 - 2018
M.Sc., Science and Engineering of Fluid Mechanics, Sorbonne Université (UPMC) and École Polytechnique (x), France
2019 - 2023
Ph.D., RWTH Aachen University, Faculty of mechanical engineering, Institute for combustion technology, Germany
2024 - present
Postdoctoral Research Associate, Institute of Fluid Dynamics and Ship Theory, Hamburg University of Technology
Major Areas of Interest & Expertise
Uncertainty quantification and Sensitivity analysis: Thermo-reactive flows, Solid fuel combustion, Chemical kinetics optimisation. Continuous and discrete adjoint sensitivity analysis, Active subspace optimisation.
Computational Fluid Dynamics (CFD): Applications in Thermo-reactive flows, Multiphase flow.
Data-driven Modeling / Machine Learning: Ships and vessels flow models, combustion models.
Publications
2024
A. Hassan, L. Schumacher, M. Sabry, V. Le Chenadec and T. Sayadi. Uncertainty quantification and sensitivity analysis of single axisymmetric particle combustion. Combustion and Flame, Volume 262, April 2024, Article number 113365.
2023
A. Hassan, M. Sabry, V. Le Chenadec, and T. Sayadi. Uncertainty quantification of kinetic models using adjoint-driven active subspace algorithms. Proceedings of the Combustion Institute Volume 39, Issue 4, 2023,Pages 5209-5218.
2021
A. Hassan, T. Sayadi, V. Le Chenadec, and A. Attili. Sensitivity analysis of an unsteady char particle combustion. Fuel, Volume 287, 2021, Article number 119738.
A. Hassan, T. Sayadi, M. Schiemann, and V. Scherer. Adjoint-based sensitivity analysis of char combustion surface reaction kinetics. Fuel, Volume 287, 2021, Article number 119503.
2020
A. Hassan, T. Sayadi, V. Le Chenadec, H. Pitsch and A. Attili. Adjoint based sensitivity analysis of steady char burn out. Com. Theo. Modeling, Volume 25, Issue 1, 2020, Pages 96-120.
Dissertation