TY - GEN
T1 - GNES-R
T2 - PHYSOR-2006 - American Nuclear Society's Topical Meeting on Reactor Physics
AU - Clarno, Kevin
AU - De Almeida, Valmor
AU - D'Azevedo, Ed
AU - De Oliveira, Cassiano
AU - Hamilton, Steven
PY - 2006
Y1 - 2006
N2 - A multilaboratory, multiuniversity collaboration has formed to advance the state-of-the-art in high-fidelity, coupled-physics simulation of nuclear energy systems. We are embarking on the first-phase in the development of a new suite of simulation tools dedicated to the advancement of nuclear science and engineering technologies. We seek to develop and demonstrate a new generation of multiphysics simulation tools that will explore the scientific phenomena of tightly coupled physics parameters within nuclear systems, support the design and licensing of advanced nuclear reactors, and provide benchmark quality solutions for code validation. In this paper, we have presented the general scope of the collaborative project and discuss the specific challenges of high-fidelity neutronics for nuclear reactor simulation and the inroads we have made along this path. The high-performance computing neutronics code system utilizes the latest version of SCALE to generate accurate, problem-dependent cross sections, which are used in NEWTRNX - a new 3-D, general-geometry, discrete-ordinates solver based on the Slice-Balance Approach. The Global Nuclear Energy Simulator for Reactors (GNES-R) team is embarking on a long-term simulation development project that encompasses multiple laboratories and universities for the expansion of high-fidelity coupled-physics simulation of nuclear energy systems.
AB - A multilaboratory, multiuniversity collaboration has formed to advance the state-of-the-art in high-fidelity, coupled-physics simulation of nuclear energy systems. We are embarking on the first-phase in the development of a new suite of simulation tools dedicated to the advancement of nuclear science and engineering technologies. We seek to develop and demonstrate a new generation of multiphysics simulation tools that will explore the scientific phenomena of tightly coupled physics parameters within nuclear systems, support the design and licensing of advanced nuclear reactors, and provide benchmark quality solutions for code validation. In this paper, we have presented the general scope of the collaborative project and discuss the specific challenges of high-fidelity neutronics for nuclear reactor simulation and the inroads we have made along this path. The high-performance computing neutronics code system utilizes the latest version of SCALE to generate accurate, problem-dependent cross sections, which are used in NEWTRNX - a new 3-D, general-geometry, discrete-ordinates solver based on the Slice-Balance Approach. The Global Nuclear Energy Simulator for Reactors (GNES-R) team is embarking on a long-term simulation development project that encompasses multiple laboratories and universities for the expansion of high-fidelity coupled-physics simulation of nuclear energy systems.
KW - 3-D general-geometry transport
KW - Coupled-physics
KW - High performance computing
KW - NEWTRNX
KW - SCALE
UR - http://www.scopus.com/inward/record.url?scp=33847201913&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:33847201913
SN - 0894486977
SN - 9780894486975
T3 - PHYSOR-2006 - American Nuclear Society's Topical Meeting on Reactor Physics
BT - PHYSOR-2006 - American Nuclear Society's Topical Meeting on Reactor Physics
Y2 - 10 September 2006 through 14 September 2006
ER -