The chemical kinetics ODEs arising from operator-split reactive-flow simulations were solved on GPUs using explicit integration algorithms. Nonstiff chemical kinetics of a hydrogen ox-idation mechanism (9 species and 38 irreversible reactions) were computed using the explicit fifth-order Runge–Kutta–Cash–Karp method, and the GPU-accelerated version performed faster than single- and six-core CPU versions by factors of 126 and 25, respectively, for 524,288 ODEs. Moderately stiff kinetics, represented with mechanisms for hydrogen/carbon-monoxide (13 species and 54 irreversible reactions) and methane (53 species and 634 irreversible reactions) oxidation, were computed using the stabilized explicit second-order Runge–Kutta–Chebyshev (RKC) algori...
Kinetic equations are used to mathematically model gas flows that are far from equilibrium due to th...
This paper presents a Graphics Processing Unit (GPU) acceleration of an iteration-based discrete vel...
Atmospheric models are a representation of dynamical, physical, chemical, dynamical, and radiative ...
<p>Presented at the 35th International Symposium on Combustion, San Francisco, CA, USA. 4-8 August 2...
This work details efforts to reduce the cost of using detailed chemical kinetic modeling in realisti...
Combustion simulations with finite-rate chemistry rely on accurate and efficient methods for solving...
Talk given in the Boulder Fluid and Thermal Sciences Seminar Series, University of Colorado, Boulder...
Graphics processing units (GPUs) are attractive for high-performance computing due to their massivel...
Numerical schemes for reacting flows typically invoke the method of fractional steps in order to iso...
Talk given at the Institute for Computational Engineering and Sciences, University of Texas at Austi...
In reacting flow simulations, considerable computational effort is spent on updating the change of c...
The focus of the current research is to develop a numerical framework on the Graphic Processing Unit...
Graphic processing units (GPUs) are powerful graphics engines featuring high levels of parallelism a...
Reaction systems represent a theoretical framework based on the regulation mechanisms of facilitatio...
Reactive force field (ReaxFF), a recent and novel bond order potential, allows for reactive molecula...
Kinetic equations are used to mathematically model gas flows that are far from equilibrium due to th...
This paper presents a Graphics Processing Unit (GPU) acceleration of an iteration-based discrete vel...
Atmospheric models are a representation of dynamical, physical, chemical, dynamical, and radiative ...
<p>Presented at the 35th International Symposium on Combustion, San Francisco, CA, USA. 4-8 August 2...
This work details efforts to reduce the cost of using detailed chemical kinetic modeling in realisti...
Combustion simulations with finite-rate chemistry rely on accurate and efficient methods for solving...
Talk given in the Boulder Fluid and Thermal Sciences Seminar Series, University of Colorado, Boulder...
Graphics processing units (GPUs) are attractive for high-performance computing due to their massivel...
Numerical schemes for reacting flows typically invoke the method of fractional steps in order to iso...
Talk given at the Institute for Computational Engineering and Sciences, University of Texas at Austi...
In reacting flow simulations, considerable computational effort is spent on updating the change of c...
The focus of the current research is to develop a numerical framework on the Graphic Processing Unit...
Graphic processing units (GPUs) are powerful graphics engines featuring high levels of parallelism a...
Reaction systems represent a theoretical framework based on the regulation mechanisms of facilitatio...
Reactive force field (ReaxFF), a recent and novel bond order potential, allows for reactive molecula...
Kinetic equations are used to mathematically model gas flows that are far from equilibrium due to th...
This paper presents a Graphics Processing Unit (GPU) acceleration of an iteration-based discrete vel...
Atmospheric models are a representation of dynamical, physical, chemical, dynamical, and radiative ...