This overview highlights relevant phenomena in a hydrogen-fueled swirl-stabilized laboratory-scale combustion chamber. The broad spectrum of length and time scales of these distinct fluid-mechanical and physical processes pose challenging requirements for simulations of turbulent hydrogen combustion requiring novel models and efficient solution strategies.
This overview highlights relevant phenomena in a hydrogen-fueled swirl-stabilized laboratory-scale combustion chamber. The broad spectrum of length and time scales of these distinct fluid-mechanical and physical processes pose challenging requirements for simulations of turbulent hydrogen combustion requiring novel models and efficient solution strategies.
Direct Numerical Simulation and Large-Eddy Simulation of turbulent reacting flows
High-order methods for reacting flows
Numerical methods in high-performance and GPU computing
All publications are listed in the publication list:
The integrated database, TUbiblio of TU Darmstadt, is currently being revised, which is why the author's complete publication list can currently only be accessed though the links above.
We would like to customise the information and usability of this website to your preferences and needs.
To this end, we use so-called cookies. Please choose which cookies you would like to enable when visiting our webpages.
Some of these cookies are required to load and correctly display this website on your device.
These are strictly necessary or essential cookies and cannot be deselected.
The preferences cookie saves your language setting, while the statistics cookie regulates
how the open-source statistical software “Matomo” analyses your visits to and activities on our website.
For more information about cookies we use, please refer to our
privacy policy.