Publications

Results 1–25 of 86

Search results

Jump to search filters

FLEXO: A Portably Performant Code for Pulsed Power Target Physics

Stagg, Alan K.; Adams, Marissa B.P.; Bond, Stephen D.; Bova, Steven W.; Cearley, Griffin S.; Cochrane, Kyle; Crockatt, Michael M.; Gardiner, Thomas A.; Granzow, Brian N.; Hamlin, Nathaniel D.; Martin, Matthew R.; Shulenburger, Luke N.; Voth, Thomas E.; Weis, Matthew R.; Woolstrum, Jeffrey M.; Yusuf, Nedim A.

FLEXO (Flux-Limited Extended-MHD Ohm's Law) is a production-line multiphysics code developed at Sandia to enable more predictive modeling of target physics on pulsed-power devices. FLEXO uses an extended magnetohydrodynamics (XMHD) model which includes a generalized Ohm's law (GOL), an electron inertia term, and Hall physics. This report describes the code's numerical methods, its computational performance, and test problems of interest.

More Details

ALEGRA: Finite element modeling for shock hydrodynamics and multiphysics

International Journal of Impact Engineering

Niederhaus, John H.J.; Bova, Steven W.; Carleton, James B.; Carpenter, John H.; Cochrane, Kyle; Crockatt, Michael M.; Dong, Wen; Fuller, Timothy J.; Granzow, Brian N.; Ibanez, Daniel A.; Kennon, Stephen R.; Luchini, Christopher B.; Moral, Ramon J.; Brien, Timothy J.; Powell, Michael J.; Robinson, Allen C.; Rodriguez, Angel E.; Sanchez, Jason J.; Scott, Walter A.; Siefert, Christopher; Stagg, Alan K.; Tezaur, Irina K.; Voth, Thomas E.; Wilkes, John R.

ALEGRA is a multiphysics finite-element shock hydrodynamics code, under development at Sandia National Laboratories since 1990. Fully coupled multiphysics capabilities include transient magnetics, magnetohydrodynamics, electromechanics, and radiation transport. Importantly, ALEGRA is used to study hypervelocity impact, pulsed power devices, and radiation effects. The breadth of physics represented in ALEGRA is outlined here, along with simulated results for a selected hypervelocity impact experiment.

More Details

ALEGRA: finite element modeling for shock hydrodynamics and multiphysics

Niederhaus, John H.J.; Powell, Michael J.; Bova, Steven W.; Carleton, James B.; Carpenter, John H.; Cochrane, Kyle; Crockatt, Michael M.; Dong, Wen; Fuller, Timothy J.; Granzow, Brian N.; Ibanez, Daniel A.; Kennon, Stephen R.; Luchini, Christopher B.; Moral, Ramon J.; Brien, Timothy J.; Robinson, Allen C.; Rodriguez, Angel E.; Sanchez, Jason J.; Scott, Walter A.; Siefert, Christopher; Stagg, Alan K.; Tezaur, Irina K.; Voth, Thomas E.

Abstract not provided.

Tetrahedral Mesh Adaptation for Lagrangian Shock Hydrodynamics

Computers and Mathematics with Applications (Oxford)

Ibanez, Daniel A.; Love, Edward; Voth, Thomas E.; Overfelt, James R.; Bays, Nathan R.; Hansen, Glen

Lagrangian shock hydrodynamics simulations will fail to proceed past a certain time if the mesh is approaching tangling. A common solution is an Arbitrary Lagrangian Eulerian (ALE) form, in which the mesh is improved (remeshing) and the solution is remapped onto the improved mesh. The simplest remeshing techniques involve moving only the nodes of the mesh. More advanced remeshing techniques involve altering the mesh connectivity in portions of the domain in order to prevent tangling. Work has been done using Voronoi-based polygonal mesh generators and 2D quad/triangle mesh adaptation. Here, this paper presents the use of tetrahedral mesh adaptation methods as the remeshing step in an otherwise Lagrangian finite element shock hydrodynamics code called Alexa.

More Details

Formulation and computation of dynamic, interface-compatible Whitney complexes in three dimensions

Journal of Computational Physics

Siefert, Christopher; Kramer, Richard M.J.; Voth, Thomas E.; Bochev, Pavel

A discrete De Rham complex enables compatible, structure-preserving discretizations for a broad range of partial differential equations problems. Such discretizations can correctly reproduce the physics of interface problems, provided the grid conforms to the interface. However, large deformations, complex geometries, and evolving interfaces makes generation of such grids difficult. We develop and demonstrate two formally equivalent approaches that, for a given background mesh, dynamically construct an interface-conforming discrete De Rham complex. Both approaches start by dividing cut elements into interface-conforming subelements but differ in how they build the finite element basis on these subelements. The first approach discards the existing non-conforming basis of the parent element and replaces it by a dynamic set of degrees of freedom of the same kind. The second approach defines the interface-conforming degrees of freedom on the subelements as superpositions of the basis functions of the parent element. These approaches generalize the Conformal Decomposition Finite Element Method (CDFEM) and the extended finite element method with algebraic constraints (XFEM-AC), respectively, across the De Rham complex.

More Details
Results 1–25 of 86
Results 1–25 of 86
Top