The Gyrokinetic Toroidal Code (GTC) is a global, three-dimensional particle-in-cell application developed to study microturbulence in tokamak fusion devices. The global capability of GTC is unique, allowing researchers to systematically analyze important dynamics such as turbulence spreading. In this work we examine a new radial domain decomposition approach to allow scalability onto the latest generation of petascale systems. Extensive performance evaluation is conducted on three high performance computing systems: the IBM BG/P, the Cray XT4, and an Intel Xeon Cluster. Overall results show that the radial decomposition approach dramatically increases scalability, while reducing the memory footprint - allowing for fusion device simulations ...
GENE solves the five-dimensional gyrokinetic equations to simulate the development and evolution of ...
After a decade where high-end computing was dominated by the rapid pace of improvements to CPU frequ...
Gyrokinetic codes in plasma physics need outstanding computational resources to solve increasingly c...
The gyrokinetic toroidal code at Princeton (GTC-P) is a highly scalable and portable particle-in-cel...
The gyrokinetic Particle-in-Cell (PIC) method is a critical computational tool enabling petascale fu...
The Gyrokinetic Toroidal Code (GTC) uses the particle-in-cell method to efficiently simulate plasma ...
Abstract. In this work, we discuss the porting to the GPU platform of the latest production version ...
The Gyrokinetic Toroidal code (GTC) (version 2) is a 3D particle-in-cell application developed at th...
The next decade of high-performance computing (HPC) systems will see a rapid evolution and divergenc...
We present multicore parallelization strategies for the particle-to-grid interpolation step in the G...
We have developed a threaded parallel data streaming approach using Globus to transfer multi-terabyt...
Reliable predictive simulation capability addressing confinement properties in magnetically confined...
The goal of the extreme scale plasma turbulence studies described in this paper is to expedite the d...
We have developed a threaded parallel data streaming approach using Globus to transfer multi-terabyt...
ABSTRACT Reliable predictive simulation capability addressing confinement properties in magnetically...
GENE solves the five-dimensional gyrokinetic equations to simulate the development and evolution of ...
After a decade where high-end computing was dominated by the rapid pace of improvements to CPU frequ...
Gyrokinetic codes in plasma physics need outstanding computational resources to solve increasingly c...
The gyrokinetic toroidal code at Princeton (GTC-P) is a highly scalable and portable particle-in-cel...
The gyrokinetic Particle-in-Cell (PIC) method is a critical computational tool enabling petascale fu...
The Gyrokinetic Toroidal Code (GTC) uses the particle-in-cell method to efficiently simulate plasma ...
Abstract. In this work, we discuss the porting to the GPU platform of the latest production version ...
The Gyrokinetic Toroidal code (GTC) (version 2) is a 3D particle-in-cell application developed at th...
The next decade of high-performance computing (HPC) systems will see a rapid evolution and divergenc...
We present multicore parallelization strategies for the particle-to-grid interpolation step in the G...
We have developed a threaded parallel data streaming approach using Globus to transfer multi-terabyt...
Reliable predictive simulation capability addressing confinement properties in magnetically confined...
The goal of the extreme scale plasma turbulence studies described in this paper is to expedite the d...
We have developed a threaded parallel data streaming approach using Globus to transfer multi-terabyt...
ABSTRACT Reliable predictive simulation capability addressing confinement properties in magnetically...
GENE solves the five-dimensional gyrokinetic equations to simulate the development and evolution of ...
After a decade where high-end computing was dominated by the rapid pace of improvements to CPU frequ...
Gyrokinetic codes in plasma physics need outstanding computational resources to solve increasingly c...