xyuan,Xingqiu Yuan,github

2d-elliptic-mesh-generator

2D orthogonal elliptic mesh generator which solves the Winslow partial differential equations

Highly interactive application for visualization and analysis of 3D multivariate gridded data, such as produced by finite element method (FEM) simulations, confocal microscopy, serial sectioning, computerized axial tomography (CAT) scans, or magnetic resonance imaging (MRI) scans

abseil-cpp

Abseil Common Libraries (C++)

absoft

acat

Assistive Context-Aware Toolkit

aces4

Parallel Computational Chemistry Application

acl

One advanced C/C++ library for Linux/Mac/FreeBSD/Solaris(x86)/Windows/Android/IOS

acousticbem

Boundary Element Method code for solving acoustic equations.

actor-framework

An Open Source Implementation of the Actor Model in C++

adept-2

Combined array and automatic differentiation library in C++

adflow

ADflow is a finite volume RANS solver tailored for gradient-based aerodynamic design optimization.

agency

Execution primitives for C++

aither

Repository for an in-progress 3D, block structured, explicit/implicit, Navier-Stokes solver.

akka

Akka Project

akumuli

Time-series database

akutan

A distributed knowledge graph store

albany

Sandia National Laboratories' Albany multiphysics code

alluxio

Memory-Speed Virtual Distributed Storage System

alsvinn

The fast Finite Volume simulator with UQ support.

am3

AM3 (Donner et al., 2011), the atmospheric component of the GFDL coupled model CM3, was designed with an awareness of key emerging issues in climate science, including aerosol-cloud interactions in climate and climate change, chemistry-climate feedbacks, land and ocean carbon cycles and their interactions with climate change, and decadal prediction. It is GFDL's first global atmospheric model to include cloud-aerosol interactions, with 20 interactive aerosol species. AM3 includes interactive tropospheric and stratospheric chemistry (85 species). AM3 uses emissions to drive its chemistry and aerosols. Its inclusion of stratospheric chemistry and dynamics will enable possible interactions between the stratosphere and troposphere on interannual scales to be included in future studies of decadal predictability. Its stratosphere has increased vertical resolution over AM2, with the uppermost level at about 1 Pascal. AM3's improved simulation of Amazon precipitation will enhance future coupling into an earth-system model. AM3 uses a cubed-sphere implementation of the finite-volume dynamical core. Earth's atmosphere is represented as a cube with six rectangular faces. There is no singularity associated with the north and south poles as with the spherical representation. Computationally, the core is highly scalable and efficient at advecting the large number of tracers associated with AM3's chemistry and aerosols. AM3 uses physically based aerosol activation (Ming et al., 2006) to form cloud droplets. All cloud parameterizations in AM2 were either replaced or augmented to include sub-grid distributions of vertical velocity required for these activation calculations. Sub-grid distributions of vertical velocity are included in AM3's stratiform clouds (Golaz et al., 2011); deep convection (Donner et al., 2001, and Wilcox and Donner, 2007) represented by an ensemble of plumes with mass fluxes and vertical velocities, simple bulk microphysics, and mesoscale updrafts and downdrafts; and shallow convection after Bretherton et al. (2004, Mon. Wea. Rev.) with buoyancy sorting, entraining plumes and vertical velocity. AM3 Code Released March 2012 The code for this model is publicly available. If you are interested in downloading the code, please do so here.

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