Back to Search Start Over

GEOS-Chem High Performance (GCHP): A next-generation implementation of the GEOS-Chem chemical transport model for massively parallel applications.

Authors :
Eastham, Sebastian D.
Long, Michael S.
Keller, Christoph A.
Lundgren, Elizabeth
Yantosca, Robert M.
Jiawei Zhuang
Chi Li
Lee, Colin J.
Yannetti, Matthew
Auer, Benjamin M.
Clune, Thomas L.
Kouatchou, Jules
Putman, William M.
Thompson, Matthew A.
Trayanov, Atanas L.
Molod, Andrea M.
Martin, Randall V.
Jacob, Daniel J.
Source :
Geoscientific Model Development Discussions; 2018, p1-18, 18p
Publication Year :
2018

Abstract

Global modeling of atmospheric composition is a grand computational challenge because of the need to simulate large coupled systems of chemical species interacting with transport on all scales. Off-line chemical transport models (CTMs), where the chemical continuity equations are solved using meteorological data as input, have the advantages of simplicity and reproducibility, and are important vehicles for developing knowledge that can then be transferred to Earth system models. However, they have generally not been designed to take advantage of massively parallel computing architectures. Here we develop such a high-performance capability (GCHP) for GEOS-Chem, a CTM driven by GEOS meteorological data from the NASA Goddard Earth Observation System (GEOS) and used by hundreds of research groups worldwide. GCHP is a grid-independent implementation of GEOS-Chem using the Earth System Modeling Framework (ESMF) that permits the same standard model to be run in a distributed-memory framework, scalable from six cores on a single node up to hundreds of cores distributed across a network. GCHP also allows GEOS-Chem to take advantage of the native GEOS cubed-sphere grid for greater accuracy and computational efficiency in simulating transport. GCHP enables GEOS-Chem simulations to be conducted with high computational scalability up to at least 500 cores, so that global simulations of stratosphere-troposphere oxidant-aerosol chemistry at C180 spatial resolution (~0.5° × 0.625°) or finer become routinely feasible. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
19919611
Database :
Complementary Index
Journal :
Geoscientific Model Development Discussions
Publication Type :
Academic Journal
Accession number :
131536571
Full Text :
https://doi.org/10.5194/gmd-2018-55