MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal Meshes

MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal Meshes

Abstract Climate model components utilizing unstructured meshes enable variable resolution, regionally enhanced simulations within global domains. Here we investigate the relationship between mesh quality and simulation statistics using the JIGSAW unstructured meshing library and the Model for Predi...

Full description

Bibliographic Details
Main Authors: Kristin E. Hoch, Mark R. Petersen, Steven R. Brus, Darren Engwirda, Andrew F. Roberts, Kevin L. Rosa, Phillip J. Wolfram
Format: Article
Language:English
Published: American Geophysical Union (AGU) 2020-03-01
Series:Journal of Advances in Modeling Earth Systems
Subjects:
ocean modeling
mesh
variable resolution
MPAS‐Ocean
mesh quality
Gulf Stream
Online Access:https://doi.org/10.1029/2019MS001848
id doaj-36949e2fc7964b569c513181271103a1
record_format Article
spelling doaj-36949e2fc7964b569c513181271103a12020-11-25T02:04:40ZengAmerican Geophysical Union (AGU)Journal of Advances in Modeling Earth Systems1942-24662020-03-01123n/an/a10.1029/2019MS001848MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal MeshesKristin E. Hoch0Mark R. Petersen1Steven R. Brus2Darren Engwirda3Andrew F. Roberts4Kevin L. Rosa5Phillip J. Wolfram6Computational Physics and Methods (CCS‐2) Los Alamos National Laboratory Los Alamos NM USAComputational Physics and Methods (CCS‐2) Los Alamos National Laboratory Los Alamos NM USAFluid Dynamics and Solid Mechanics (T‐3) Los Alamos National Laboratory Los Alamos NM USANASA Goddard Institute for Space Studies New York NY USAFluid Dynamics and Solid Mechanics (T‐3) Los Alamos National Laboratory Los Alamos NM USAComputational Physics and Methods (CCS‐2) Los Alamos National Laboratory Los Alamos NM USAFluid Dynamics and Solid Mechanics (T‐3) Los Alamos National Laboratory Los Alamos NM USAAbstract Climate model components utilizing unstructured meshes enable variable resolution, regionally enhanced simulations within global domains. Here we investigate the relationship between mesh quality and simulation statistics using the JIGSAW unstructured meshing library and the Model for Prediction Across Scales‐Ocean (MPAS‐Ocean) with a focus on Gulf Stream dynamics. In the base configuration, the refined region employs 8 km cells that extend 400 km from the coast of North America. This coastal‐refined region is embedded within a low‐resolution global domain, with cell size varying latitudinally between 30 and 60 km. The resolution transition region between the refined region and background mesh is 600 km wide. Three sensitivity tests are conducted: (a) The quality of meshes is intentionally degraded so that horizontal cells are progressively more distorted; (b) the transition region from high to low resolution is steepened; and (c) resolution of the coastal refinement region is varied from 30 to 8 km. Overall, the ocean simulations are shown to be robust to mesh resolution and quality alterations. Meshes that are substantially degraded still produce realistic currents, with Southern Ocean transports within 0.4% and Gulf Stream transports within 12% of high‐quality mesh results. The narrowest transition case of 100 km did not produce any spurious effects. Refined regions with high‐resolution produce eddy kinetic energy and sea surface height variability that are similar to the high‐resolution reference simulation. These results provide heuristics for the design criteria of variable‐resolution climate model domains.https://doi.org/10.1029/2019MS001848ocean modelingmeshvariable resolutionMPAS‐Oceanmesh qualityGulf Stream
collection DOAJ
language English
format Article
sources DOAJ
author Kristin E. Hoch
Mark R. Petersen
Steven R. Brus
Darren Engwirda
Andrew F. Roberts
Kevin L. Rosa
Phillip J. Wolfram
spellingShingle Kristin E. Hoch
Mark R. Petersen
Steven R. Brus
Darren Engwirda
Andrew F. Roberts
Kevin L. Rosa
Phillip J. Wolfram
MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal Meshes
Journal of Advances in Modeling Earth Systems
ocean modeling
mesh
variable resolution
MPAS‐Ocean
mesh quality
Gulf Stream
author_facet Kristin E. Hoch
Mark R. Petersen
Steven R. Brus
Darren Engwirda
Andrew F. Roberts
Kevin L. Rosa
Phillip J. Wolfram
author_sort Kristin E. Hoch
title MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal Meshes
title_short MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal Meshes
title_full MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal Meshes
title_fullStr MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal Meshes
title_full_unstemmed MPAS‐Ocean Simulation Quality for Variable‐Resolution North American Coastal Meshes
title_sort mpas‐ocean simulation quality for variable‐resolution north american coastal meshes
publisher American Geophysical Union (AGU)
series Journal of Advances in Modeling Earth Systems
issn 1942-2466
publishDate 2020-03-01
description Abstract Climate model components utilizing unstructured meshes enable variable resolution, regionally enhanced simulations within global domains. Here we investigate the relationship between mesh quality and simulation statistics using the JIGSAW unstructured meshing library and the Model for Prediction Across Scales‐Ocean (MPAS‐Ocean) with a focus on Gulf Stream dynamics. In the base configuration, the refined region employs 8 km cells that extend 400 km from the coast of North America. This coastal‐refined region is embedded within a low‐resolution global domain, with cell size varying latitudinally between 30 and 60 km. The resolution transition region between the refined region and background mesh is 600 km wide. Three sensitivity tests are conducted: (a) The quality of meshes is intentionally degraded so that horizontal cells are progressively more distorted; (b) the transition region from high to low resolution is steepened; and (c) resolution of the coastal refinement region is varied from 30 to 8 km. Overall, the ocean simulations are shown to be robust to mesh resolution and quality alterations. Meshes that are substantially degraded still produce realistic currents, with Southern Ocean transports within 0.4% and Gulf Stream transports within 12% of high‐quality mesh results. The narrowest transition case of 100 km did not produce any spurious effects. Refined regions with high‐resolution produce eddy kinetic energy and sea surface height variability that are similar to the high‐resolution reference simulation. These results provide heuristics for the design criteria of variable‐resolution climate model domains.
topic ocean modeling
mesh
variable resolution
MPAS‐Ocean
mesh quality
Gulf Stream
url https://doi.org/10.1029/2019MS001848
work_keys_str_mv AT kristinehoch mpasoceansimulationqualityforvariableresolutionnorthamericancoastalmeshes
AT markrpetersen mpasoceansimulationqualityforvariableresolutionnorthamericancoastalmeshes
AT stevenrbrus mpasoceansimulationqualityforvariableresolutionnorthamericancoastalmeshes
AT darrenengwirda mpasoceansimulationqualityforvariableresolutionnorthamericancoastalmeshes
AT andrewfroberts mpasoceansimulationqualityforvariableresolutionnorthamericancoastalmeshes
AT kevinlrosa mpasoceansimulationqualityforvariableresolutionnorthamericancoastalmeshes
AT phillipjwolfram mpasoceansimulationqualityforvariableresolutionnorthamericancoastalmeshes
_version_ 1724941792297615360

Similar Items