| Monday 24 September |
| 10:30-10:55 |
John Thuburn, (University of Exeter) |
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Mimetic Semi-implicit Solution of the Shallow Water Equations on Hexagonal-Icosahedral and Cubed-Sphere Grids | Sem 1 |
| 10:55-11:20 |
Thomas Dubos, (École Polytechnique) |
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Variational derivation of energy-conserving finite-difference schemes for geophysical fluid equations | Sem 1 |
| 11:20-11:45 |
Colin Cotter, (Imperial College London) |
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Finite element exterior calculus framework for geophysical fluid dynamics | Sem 1 |
| 11:45-12:10 |
Stefan Vater, (Freie Universität Berlin) |
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A multilevel time integrator for computing longwave shallow water flows at low Froude numbers | Sem 1 |
| 14:00-14:25 |
Sergey Danilov, (Alfred-Wegener-Institut für Polar- und Meeresforschung (AWI)) |
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Multiscale ocean simulations with FESOM | Sem 1 |
| 14:25-14:50 |
Jürgen Steppeler, (Deutscher Wetterdienst (DWD)) |
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Uniformly third Order conserving Schems on Polygonal Grids | Sem 1 |
| 14:50-15:15 |
Ramachandran Nair, (National Center for Atmospheric Research) |
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A Semi-Lagrangian Discontinuous Galerkin (SLDG) Conservative Transport Scheme on the Cubed-Sphere | Sem 1 |
| 15:45-16:10 |
Jean-Pierre Croisille, (Université de Lorraine) |
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Compact finite difference schemes on the Cubed-Sphere | Sem 1 |
| 16:10-16:35 |
Nicholas Kevlahan, (McMaster University) |
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A conservative adaptive wavelet method for the shallow water equations on staggered grids | Sem 1 |
| 16:35-17:00 |
Tae-Jin Oh, (Korea Institute of Atmospheric Prediction Systems (KIAPS)) |
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Dynamical Core Developments at KIAPS | Sem 1 |
| Tuesday 25 September |
| 09:00-09:25 |
Sarvesh Kumar Dubey, (Indian Institute of Technology) |
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Slope-limited transport schemes using icosahedral hexagonal grid | Sem 1 |
| 09:25-09:50 |
Oswald Knoth, (Leibniz Institute for Tropospheric Research, Leipzig) |
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Numerical Solution of the Advection Equation on Unstructured Spherical Grids with Logarithmic Reconstruction | Sem 1 |
| 09:50-10:15 |
Janakiraman Subburathnam, (Centre for Development of Advanced Computing, (C-DAC)) |
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Linear advection characteristics of a variable resolution global spectral method on the sphere | Sem 1 |
| 10:15-10:40 |
Kara Peterson, (Sandia National Laboratories) |
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Optimization-based Conservative Transport on the Sphere | Sem 1 |
| 11:10-11:35 |
Colin Zarzycki, (University of Michigan) |
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Improving tropical cyclone representation in general circulation models through the use of variable resolution | Sem 1 |
| 11:35-12:00 |
Phillip Colella, (Lawrence Berkeley National Laboratory) |
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Adaptive High-order Finite Volume Discretizations on Spherical Thin Shells | Sem 1 |
| 12:00-12:25 |
Jonathan Lambrechts, (Université Catholique de Louvain ) |
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Generation of Provably Correct Curvilinear Meshes | Sem 1 |
| 14:00-14:25 |
Donna Calhoun, (Boise State University) |
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A logically Cartesian, adaptively refined two-patch sphere grid for modeling transport in the atmosphere | Sem 1 |
| 14:25-14:50 |
Andreas Müller, (Naval Postgraduate School) |
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Accuracy of adaptive discontinuous Galerkin simulations | Sem 1 |
| 14:50-15:15 |
Giovanni Tumolo, (Abdus Salam International Centre for Theoretical Physics) |
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A semi-implicit, semi-Lagrangian, p-adaptive Discontinuous Galerkin method for the rotating shallow water equations | Sem 1 |
| 15:45-16:10 |
Peter Bosler, (University of Michigan) |
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Particle methods for geophysical flow on the sphere | Sem 1 |
| 16:10-16:35 |
John Boyd, (University of Michigan) |
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Progress in Radial Basis Function Methods: Adaptive Vortex-RBF Methods for the Sphere and Other Advances | Sem 1 |
| 16:35-17:00 |
Michal Kopera, (Naval Postgraduate School) |
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Adaptive mesh refinement for discontinuous Galerkin method on quadrilateral non-conforming grid | Sem 1 |
| 17:00-17:25 |
Evaggelos Kritsikis, (Laboratoire des Sciences du Climat et l'Environnement (LSCE)) |
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Second-order conservative remapping between unstructured spherical meshes | Sem 1 |
| Thursday 27 September |
| 09:00-09:25 |
Todd Ringler, (Los Alamos National Laboratory) |
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A Multi-Resolution Modeling Approach for Global Ocean Modeling | Sem 1 |
| 09:25-09:50 |
Jared Whitehead, (Los Alamos National Laboratory) |
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Potential Vorticity: A Diagnostic Tool for General Circulation Models | Sem 1 |
| 09:50-10:15 |
Peter Lauritzen, (National Center for Atmospheric Research) |
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A standard test case suite for two-dimensional linear transport on the sphere | Sem 1 |
| 10:15-10:40 |
Mike Cullen, (Met Office) |
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Evaluating numerical methods by using asymptotic limit solutions | Sem 1 |
| 11:10-11:35 |
Paul Ullrich, (University of California, Davis) |
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MCore: Towards a Multi-Resolution Non-Hydrostatic Finite-Volume Dynamical Core | Sem 1 |
| 11:35-12:00 |
Jin Lee, (National Oceanic and Atmosphere Administration) |
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A Three-Dimensional Finite-Volume Nonhydrostatic Icosahedral Modle (NIM) | Sem 1 |
| 12:00-12:25 |
Xingliang Li, (China Meteorological Administration) |
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A multi-moment constrained finite volume model for non-hydrostatic atmospheric dynamics | Sem 1 |
| 13:35-14:00 |
James Kent, (University of Michigan) |
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DCMIP 2012: Tracer Transport Tests in Dynamical Cores | Sem 1 |
| 14:00-14:25 |
Sasa Gabersek, (Naval Research Laboratory) |
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Numerical Simulations with a Three-Dimensional Spectral Element Model | Sem 1 |
| 14:25-14:50 |
Celal Konor, (Colorado State University) |
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Design of a dynamical core based on the nonhydrostatic unified system of equations | Sem 1 |
| 14:50-15:15 |
Almut Gassmann, (Leibniz-Institut für Atmosphärenphysik, Kühlungsborn) |
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ICON-IAP: A non-hydrostatic global model designed for energetic consistency | Sem 1 |
| 15:45-16:10 |
Nils Wedi, (European Centre for Medium-Range Weather Forecasts (ECMWF)) |
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Global, non-hydrostatic, cloud-permitting, medium-range forecasts using the spectral transform method: progress and challenges | Sem 1 |
| 16:10-16:35 |
Michail Diamantakis, (European Centre for Medium-Range Weather Forecasts (ECMWF)) |
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Evaluation of mass fixing schemes for the ECMWF Integrated Forecasting System (IFS) | Sem 1 |
| 16:35-17:00 |
Michael Baldauf, (Deutscher Wetterdienst (DWD)) |
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An exact analytical solution for gravity wave expansion of the compressible, non-hydrostatic Euler equations on the sphere | Sem 1 |
| 17:00-17:25 |
Christiane Jablonowski, (University of Michigan) |
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Highlights of the Dynamical Core Model Intercomparison Project (DCMIP) | Sem 1 |
| Friday 28 September |
| 09:00-09:25 |
Günther Zängl, (Deutscher Wetterdienst (DWD)) |
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The Icosahedral Nonhydrostatic (ICON) model: formulation of the dynamical core and physics-dynamics coupling | Sem 1 |
| 09:25-09:50 |
Mark Taylor, (Sandia National Laboratories) |
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CAM high-resolution AMIP simulations using a spectral finite element dynamical core | Sem 1 |
| 09:50-10:15 |
John McGregor, (CSIRO Marine and Atmospheric Research (CMAR)) |
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Comparing the formulations of CCAM and VCAM and their performance as atmospheric GCMs | Sem 1 |
| 10:15-10:40 |
Thomas Melvin, , Nigel Wood, (Met Office) |
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The dynamical core of the Met Office's Unified Model | Sem 1 |
| 11:10-11:35 |
Abdessamad Qaddouri, (Environment Canada) |
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The CMC 15-Km operational deterministic global forecast system with Yin-Yang grid | Sem 1 |
| 11:35-12:00 |
William Skamarock, (National Center for Atmospheric Research) |
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The global nonhydrostatic atmospheric model MPAS: Preliminary results from variable-resolution mesh tests | Sem 1 |
| 12:00-12:25 |
Florian Prill, (Deutscher Wetterdienst (DWD)) |
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The Icosahedral Nonhydrostatic (ICON) model: Scalability on Massively Parallel Computer Architectures | Sem 1 |
| 13:30-13:55 |
Hirofumi Tomita, (RIKEN/AICS) |
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SCALE-LES: Strategic development of large eddy simulation suitable to the future HPC | Sem 1 |
| 13:55-14:20 |
Ryuji Yoshida, (RIKEN/AICS) |
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An Inter-Comparison of Icosahedral Climate Models on the G8 Call: ICOMEX Project | Sem 1 |
| 14:20-14:45 |
Jean Côté, (UQAM - Université du Québec à Montréal) |
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Time-parallel algorithms for weather prediction and climate simulation | Sem 1 |
| Tuesday 23 October |
| 09:30-10:05 |
Günther Zängl, (Deutscher Wetterdienst) |
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The ICON model and its relationship to the ICOMEX project | Satellite |
| 10:05-10:40 |
Todd Ringler, (LANL) |
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Jones and Jacobsen "Can Models Built upon Unstructured Grids be Computationally Competitive on Emerging High-Performace Architectures? | Satellite |
| 11:00-11:45 |
Michael Baldauf, (Deutscher Wetterdienst) |
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Limited area model weather prediction using COSMO with emphasis on the numerics of dynamical cores (including some remarks on the NEC vector supercomputer) | Satellite |
| 11:45-12:10 |
John Thuburn, , Colin Cotter, (Exeter/Imperial College) |
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A primal-dual mixed finite element method for accurate and efficient atmospheric modelling on massively parallel computers | Satellite |
| 12:10-12:35 |
Jean Côté, (UQAM) |
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Time-parallel algorithms for weather prediction and climate simulation | Satellite |
| 13:30-14:15 |
Henry Weller, (OpenCFD Limited) |
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Addressing unstructuredness and hardware and software divergence | Satellite |
| 14:15-14:40 |
Francis X. Giraldo, , James F. Kelly, , Shiva Gopalakrishnan, (Naval Postgraduate School) |
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Development of a Nonhydrostatic Unified Atmospheric Model (NUMA) on Multi-Core and Many-core Computer Architectures | Satellite |
| 15:10-15:55 |
Andy Grant, (IBM) |
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tba | Satellite |
| 16:00-16:25 |
David Ham, , Patrick E. Farrell, , Simon W. Funke, (Imperial College London) |
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Fully automatic adjoints: a robust and efficient mechanism for generating adjoint dynamical cores | Satellite |
| 16:45-17:20 |
Peter Jimack, (Leeds) |
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On the Development of Implicit Solvers for Time-Dependent Systems | Satellite |
| Wednesday 24 October |
| 09:30-10:05 |
John McGregor, (CSIRO) |
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Cube-based atmospheric GCMs at CSIRO | Satellite |
| 10:05-10:40 |
Stephane Popinet, (NIWA) |
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Quadtree-adaptive global atmospheric modelling on parallel systems | Satellite |
| 11:00-11:45 |
Mark Taylor, (Sandia) |
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High resolution and variable resolution capabilities of the Community Atmosphere Model (CAM) with a spectral finite element dynamical core | Satellite |
| 11:45-12:10 |
Colin M. Zarzycki, , Christiane Jablonowski, (University of Michigan) |
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Evaluating Variable-Resolution CAM-SE as a Numerical Weather Prediction Tool | Satellite |
| 12:10-12:35 |
Marcus J Thatcher, , John L McGregor, (CSIRO) |
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A prototype model for coupled simulations of regional climate suitable for massively parallel architectures | Satellite |
| 13:30-14:15 |
Tom Edwards, (Cray Inc.) |
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Earth system modeling strategies on extreme scale architectures | Satellite |
| 14:15-14:40 |
Eike Mueller, , Robert Scheichl, (University of Bath) |
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Scalability of Elliptic Solvers in Numerical Weather and Climate Prediction | Satellite |
| 15:10-15:55 |
Max Gunzberger, (Florida State ) |
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Parallel Algorithm for Spherical Delaunay Triangulations and Spherical Centroidal Voronoi Tessellations | Satellite |
| 16:00-16:25 |
Robert Scheichl, (University of Bath) |
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Multilevel Markov-Chain Monte Carlo Methods for Large Scale Problems | Satellite |
| 16:45-17:20 |
Richard Loft, (UCAR) |
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Meeting the Challenge of Many-core Architectures in Weather and Climate Models | Satellite |
