Publications

Mayr, Matthias M.; Cyr, Eric C.; Shadid, John N.; Pawlowski, Roger P.; Wildey, Timothy M.; Scovazzi, Guglielmo S.; Zeng, Xianyi Z.; Phillips, Edward G.; Conde, Sidafa C.

Abstract not provided.

Mayr, Matthias M.; Cyr, Eric C.; Shadid, John N.; Pawlowski, Roger P.; Wildey, Timothy M.; Scovazzi, Guglielmo S.; Zeng, Xianyi Z.; Phillips, Edward G.; Conde, Sidafa C.

Abstract not provided.

Lin, Paul L.; Shadid, John N.; Phillips, Edward G.; Hu, Jonathan J.; Cyr, Eric C.; Pawlowski, Roger P.; Tsuji, Paul T.; Sondak, David S.

Abstract not provided.

Lin, Paul L.; Shadid, John N.; Pawlowski, Roger P.; Bettencourt, Matthew T.; Cyr, Eric C.

Abstract not provided.

Pawlowski, Roger P.

Abstract not provided.

Ober, Curtis C.; Bartlett, Roscoe B.; Coffey, Todd S.; Pawlowski, Roger P.

Time integration is a central component for most transient simulations. It coordinates many of the major parts of a simulation together, e.g., a residual calculation with a transient solver, solution with the output, various operator-split physics, and forward and adjoint solutions for inversion. Even though there is this variety in these transient simulations, there is still a common set of algorithms and proce- dures to progress transient solutions for ordinary-differential equations (ODEs) and differential-alegbraic equations (DAEs). Rythmos is a collection of these algorithms that can be used for the solution of transient simulations. It provides common time-integration methods, such as Backward and Forward Euler, Explicit and Im- plicit Runge-Kutta, and Backward-Difference Formulas. It can also provide sensitivities, and adjoint components for transient simulations. Rythmos is a package within Trilinos, and requires some other packages (e.g., Teuchos and Thrya) to provide basic time-integration capabilities. It also can be cou- pled with several other Trilinos packages to provide additional capabilities (e.g., AztecOO and Belos for linear solutions, and NOX for non-linear solutions). The documentation is broken down into three parts: Theory Manual, User's Manual, and Developer's Guide. The Theory Manual contains the basic theory of the time integrators, the nomenclature and mathematical structure utilized within Rythmos, and verification results demonstrating that the designed order of accuracy is achieved. The User's Manual provides information on how to use the Rythmos, description of input parameters through Teuchos Parameter Lists, and description of convergence test examples. The Developer's Guide is a high-level discussion of the design and structure of Rythmos to provide information to developers for the continued development of capabilities. Details of individual components can be found in the Doxygen webpages. Notice: This document is a collection of notes gathered over many years, however its development has been dormant for the past several years due to the lack of funding. Pre-release copies of this document have circulated to internal Sandia developers, who have found it useful in their application development. Also external Sandia developers have made inquiries for additional Rythmos documentation. To make this documentation publicly available, we are releasing this documentation in an " as-is " condition. We apologize for its incomplete state and obvious lack of readability, however we hope that the information contained in this document will still be helpful to users in their application development.

Lin, Paul L.; Shadid, John N.; Phillips, Edward G.; Hu, Jonathan J.; Cyr, Eric C.; Pawlowski, Roger P.; Prokopenko, Andrey P.; Tsuji, Paul T.

Abstract not provided.

Gates, Jason M.; Pawlowski, Roger P.; Cyr, Eric C.

Abstract not provided.

Pawlowski, Roger P.; Bartlett, Roscoe B.; Bettencourt, Matthew T.; Carleton, James B.; Conde, Sidafa C.; Cyr, Eric C.; Kim, Kyungjoo K.; Mota, Alejandro M.; Perego, Mauro P.; Shadid, John N.; Sjaardema, Gregory D.; Toth, Alexander R.; Bradley, Andrew M.; Spotz, William S.; Ober, Curtis C.; Kalashnikova, Irina

Abstract not provided.

Ober, Curtis C.; Pawlowski, Roger P.; Cyr, Eric C.

Abstract not provided.

Pawlowski, Roger P.

Abstract not provided.

Cyr, Eric C.; Shadid, John N.; Wildey, Timothy M.; Phillips, Edward G.; Robinson, Allen C.; Miller, Sean M.; Pawlowski, Roger P.

Abstract not provided.

Shadid, John N.; Phillips, Edward G.; Cyr, Eric C.; Pawlowski, Roger P.; Bettencourt, Matthew T.; Cartwright, Keith C.; Lin, Paul L.; Kramer, Richard M.; Niederhaus, John H.; Radtke, Gregg A.; Robinson, Allen C.

Abstract not provided.

Journal of Computational Physics

Shadid, John N.; Smith, Thomas M.; Cyr, E.C.; Wildey, T.M.; Pawlowski, Roger P.

A critical aspect of applying modern computational solution methods to complex multiphysics systems of relevance to nuclear reactor modeling, is the assessment of the predictive capability of specific proposed mathematical models. In this respect the understanding of numerical error, the sensitivity of the solution to parameters associated with input data, boundary condition uncertainty, and mathematical models is critical. Additionally, the ability to evaluate and or approximate the model efficiently, to allow development of a reasonable level of statistical diagnostics of the mathematical model and the physical system, is of central importance. In this study we report on initial efforts to apply integrated adjoint-based computational analysis and automatic differentiation tools to begin to address these issues. The study is carried out in the context of a Reynolds averaged Navier-Stokes approximation to turbulent fluid flow and heat transfer using a particular spatial discretization based on implicit fully-coupled stabilized FE methods. Initial results are presented that show the promise of these computational techniques in the context of nuclear reactor relevant prototype thermal-hydraulics problems.

Lin, Paul L.; Shadid, John N.; Hu, Jonathan J.; Pawlowski, Roger P.; Cyr, Eric C.; Prokopenko, Andrey V.

Abstract not provided.

Bettencourt, Matthew T.; Cyr, Eric C.; Pawlowski, Roger P.; Kramer, Richard M.; Phillips, Edward G.; Shadid, John N.; Robinson, Allen C.

Abstract not provided.

Computer Methods in Applied Mechanics and Engineering

Shadid, John N.; Pawlowski, Roger P.; Cyr, E.C.; Tuminaro, Raymond S.; Chacón, L.; Weber, Paula D.

The computational solution of the governing balance equations for mass, momentum, heat transfer and magnetic induction for resistive magnetohydrodynamics (MHD) systems can be extremely challenging. These difficulties arise from both the strong nonlinear, nonsymmetric coupling of fluid and electromagnetic phenomena, as well as the significant range of time- and length-scales that the interactions of these physical mechanisms produce. This paper explores the development of a scalable, fully-implicit stabilized unstructured finite element (FE) capability for 3D incompressible resistive MHD. The discussion considers the development of a stabilized FE formulation in context of the variational multiscale (VMS) method, and describes the scalable implicit time integration and direct-to-steady-state solution capability. The nonlinear solver strategy employs Newton-Krylov methods, which are preconditioned using fully-coupled algebraic multilevel preconditioners. These preconditioners are shown to enable a robust, scalable and efficient solution approach for the large-scale sparse linear systems generated by the Newton linearization. Verification results demonstrate the expected order-of-accuracy for the stabilized FE discretization. The approach is tested on a variety of prototype problems, that include MHD duct flows, an unstable hydromagnetic Kelvin-Helmholtz shear layer, and a 3D island coalescence problem used to model magnetic reconnection. Initial results that explore the scaling of the solution methods are also presented on up to 128K processors for problems with up to 1.8B unknowns on a CrayXK7.

Bettencourt, Matthew T.; Cyr, Eric C.; Pawlowski, Roger P.; Kramer, Richard M.; Phillips, Edward G.; Shadid, John N.; Robinson, Allen C.

Abstract not provided.

Journal of Computational Physics

Hamilton, Steven; Berrill, Mark; Clarno, Kevin; Pawlowski, Roger P.; Toth, Alex; Kelley, C.T.; Evans, Thomas; Philip, Bobby

This paper evaluates the performance of multiphysics coupling algorithms applied to a light water nuclear reactor core simulation. The simulation couples the k-eigenvalue form of the neutron transport equation with heat conduction and subchannel flow equations. We compare Picard iteration (block Gauss-Seidel) to Anderson acceleration and multiple variants of preconditioned Jacobian-free Newton-Krylov (JFNK). The performance of the methods are evaluated over a range of energy group structures and core power levels. A novel physics-based approximation to a Jacobian-vector product has been developed to mitigate the impact of expensive on-line cross section processing steps. Numerical simulations demonstrating the efficiency of JFNK and Anderson acceleration relative to standard Picard iteration are performed on a 3D model of a nuclear fuel assembly. Both criticality (k-eigenvalue) and critical boron search problems are considered.

Cyr, Eric C.; Shadid, John N.; Phillips, Edward G.; Pawlowski, Roger P.; Seefeldt, Ben S.

Abstract not provided.

Journal of Computational Physics

Sondak, D.; Shadid, John N.; Oberai, A.A.; Pawlowski, Roger P.; Cyr, E.C.; Smith, Thomas M.

New large eddy simulation (LES) turbulence models for incompressible magnetohydrodynamics (MHD) derived from the variational multiscale (VMS) formulation for finite element simulations are introduced. The new models include the variational multiscale formulation, a residual-based eddy viscosity model, and a mixed model that combines both of these component models. Each model contains terms that are proportional to the residual of the incompressible MHD equations and is therefore numerically consistent. Moreover, each model is also dynamic, in that its effect vanishes when this residual is small. The new models are tested on the decaying MHD Taylor Green vortex at low and high Reynolds numbers. The evaluation of the models is based on comparisons with available data from direct numerical simulations (DNS) of the time evolution of energies as well as energy spectra at various discrete times. A numerical study, on a sequence of meshes, is presented that demonstrates that the large eddy simulation approaches the DNS solution for these quantities with spatial mesh refinement.

Phillips, Edward G.; Shadid, John N.; Cyr, Eric C.; Pawlowski, Roger P.

Abstract not provided.

Lin, Paul L.; Shadid, John N.; Hu, Jonathan J.; Cyr, Eric C.; Pawlowski, Roger P.; Prokopenko, Andrey V.

Abstract not provided.

Lin, Paul L.; Shadid, John N.; Hu, Jonathan J.; Cyr, Eric C.; Pawlowski, Roger P.; Prokopenko, Andrey V.

Abstract not provided.

Pawlowski, Roger P.; Salinger, Andrew G.

Abstract not provided.