Large Eddy Simulations (LES) of turbulent reacting flows carried out with detailed kinetic mechanisms have a key role for the discovery of the physical and chemical processes occurring in combustion systems, and are essential for the development of efficient, stable, and non-pollutant technologies. Nevertheless, these simulations require a large amount of computational resources, making their utilization for large-scale systems, such as industrial burners and gas turbines, impractical. In this work, we combine state-of-the-art machine learning algorithms and model reduction methods to deliver a fully automated strategy for performing LES with adaptive chemistry. This strategy is based on the Sample-Partitioning Adaptive Chemistry (SPARC) al...
A strategy based on machine learning is discussed to close the gap between the detailed description ...
In this study, we combine the SPARC (Sample-Partitioning Adaptive Reduced Chemistry) and the Cell Ag...
Accurate, efficient prediction of reacting flow systems is challenging due to stiff reaction kinetic...
Large Eddy Simulations (LES) of turbulent reacting flows carried out with detailed kinetic mechanism...
Combustion science must necessarily go through a deep process of innovation, as only improving the e...
Combustion plays an important role on the energy production network throughout the entire world, fro...
The large number of species included in the detailed kinetic mechanisms represents a serious challen...
The large number of species included in the detailed kinetic mechanisms represents a serious challen...
A new machine learning methodology is proposed for speeding up thermochemistry computations in simul...
This work proposes a chemical mechanism tabulation method using artificial neural networks (ANNs) fo...
In Large Eddy Simulations (LES) of combustion, the accuracy of predictions might be heavily affected...
232 pagesIn this time of severe climate change, there is an increasing need for sophisticated simula...
A major challenge in the numerical simulations of turbulent reacting flows in-volving large numbers ...
International audienceFlame ignition, stabilization and extinction or pollutant predictions are cruc...
Despite the onset of peta-scale computing, simulations of reacting flows with detailed chemistry is ...
A strategy based on machine learning is discussed to close the gap between the detailed description ...
In this study, we combine the SPARC (Sample-Partitioning Adaptive Reduced Chemistry) and the Cell Ag...
Accurate, efficient prediction of reacting flow systems is challenging due to stiff reaction kinetic...
Large Eddy Simulations (LES) of turbulent reacting flows carried out with detailed kinetic mechanism...
Combustion science must necessarily go through a deep process of innovation, as only improving the e...
Combustion plays an important role on the energy production network throughout the entire world, fro...
The large number of species included in the detailed kinetic mechanisms represents a serious challen...
The large number of species included in the detailed kinetic mechanisms represents a serious challen...
A new machine learning methodology is proposed for speeding up thermochemistry computations in simul...
This work proposes a chemical mechanism tabulation method using artificial neural networks (ANNs) fo...
In Large Eddy Simulations (LES) of combustion, the accuracy of predictions might be heavily affected...
232 pagesIn this time of severe climate change, there is an increasing need for sophisticated simula...
A major challenge in the numerical simulations of turbulent reacting flows in-volving large numbers ...
International audienceFlame ignition, stabilization and extinction or pollutant predictions are cruc...
Despite the onset of peta-scale computing, simulations of reacting flows with detailed chemistry is ...
A strategy based on machine learning is discussed to close the gap between the detailed description ...
In this study, we combine the SPARC (Sample-Partitioning Adaptive Reduced Chemistry) and the Cell Ag...
Accurate, efficient prediction of reacting flow systems is challenging due to stiff reaction kinetic...