The progress made in accelerating simulations of fluid flow using GPUs, and the challenges
that remain, are surveyed. The review first provides an introduction to GPU computing and …

Compressible reacting flows may display sharp spatial variation related to shocks, contact
discontinuities or reactive zones embedded within relatively smooth regions. The presence …

Accurate simulations of combustion phenomena require the use of detailed chemical
kinetics in order to capture limit phenomena such as ignition and extinction as well as …

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 …

Simulating multi-dimensional combustion with detailed kinetics often requires solving a
large number of ordinary differential equation (ODE) problems at each global time step. In …

Recent progress in machine learning (ML) and high-performance computing (HPC) have
brought potentially game-changing opportunities in accelerating reactive flow simulations. In …

As heterogeneous computing platforms become more prevalent, the programmer must
account for complex memory hierarchies in addition to the difficulties of parallel …

The solution of reactive computational fluid dynamics (CFD) simulations is accelerated by
the implementation of a hybrid central processing unit/graphics processing units (CPU/GPU) …

Competing workloads on a shared storage system cause I/O resource contention and
application performance vagaries. This problem is already evident in today's HPC storage …

Geoscience simulations rely heavily on high performance computing (HPC) systems. To
date, many CPU/GPU heterogeneous HPC systems have been established on which many …