Publications

Pham, Julie V.; Hubbard, Neal B.; Dohner, Jeffrey L.; Pasik, Michael F.

Abstract not provided.

Turner, C.D.; Pasik, Michael F.; Seidel, David B.; Pointon, Timothy D.; Cartwright, Keith C.; Kramer, Richard M.; McGregor, Duncan A.

The Unstructured Time-Domain ElectroMagnetics (UTDEM) portion of the EMPHASIS suite solves Maxwell’s equations using finite-element techniques on unstructured meshes. This document provides user-specific information to facilitate the use of the code for applications of interest.

Pasik, Michael F.

Abstract not provided.

Pasik, Michael F.

Abstract not provided.

Turner, C.D.; Pasik, Michael F.; Pointon, Timothy D.; Pointon, Timothy D.; Cartwright, Keith C.

The Unstructured Time - Domain ElectroMagnetics (UTDEM) portion of the EMPHASIS suite solves Maxwell's equations using finite - element techniques on unstructured meshes. This document provides user - specific information to facilitate the use of the code for ap plications of interest. Acknowledgement The authors would like to thank all of those individuals who have helped to bring EMPHASIS/Nevada to the point it is today, including Bill Bohnhoff, Rich Drake, and all of the NEVADA code team.

Simpson, Sean S.; Coats, Rebecca S.; Hjalmarson, Harold P.; Jorgenson, Roy E.; Pasik, Michael F.

This report documents work conducted in FY13 on electrical discharge experiments performed to develop predictive computational models of the fundamental processes of surface breakdown in the vicinity of high-permittivity material interfaces. Further, experiments were conducted to determine if free carrier electrons could be excited into the conduction band thus lowering the effective breakdown voltage when UV photons (4.66 eV) from a high energy pulsed laser were incident on the rutile sample. This report documents the numerical approach, the experimental setup, and summarizes the data and simulations. Lastly, it describes the path forward and challenges that must be overcome in order to improve future experiments for characterizing the breakdown behavior for rutile.

Pasik, Michael F.; Coats, Rebecca S.; Jorgenson, Roy E.; Hjalmarson, Harold P.

Abstract not provided.

Pasik, Michael F.; Coats, Rebecca S.; Jorgenson, Roy E.; Hjalmarson, Harold P.

Abstract not provided.

Jorgenson, Roy E.; Pasik, Michael F.; Coats, Rebecca S.; Hjalmarson, Harold P.; Lehr, J.M.; DiAntonio, Christopher D.; Wallace, Zachariah R.

Abstract not provided.

Digest of Technical Papers-IEEE International Pulsed Power Conference

VanDevender, J.P.; Langston, William L.; Pasik, Michael F.; Coats, Rebecca S.; Pointon, Timothy D.; Seidel, David B.; Jennings, C.A.; McKee, G.R.; Schneider, Larry X.

We have developed a new type of convolute called the Clam Shell MITL (CSMITL) to couple multi-level accelerators to a common load. The CSMITL has magnetic nulls only at large radius where the cathode electric field is kept below the threshold for emission, has only a simply connected magnetic topology to avoid plasma motion along magnetic field lines into highly stressed gaps, and has electron injectors that ensure efficient electron flow even in the limiting case of self-limited MITLs. We report the first experimental results on a CSMITL, which convolutes two disk feeds on the Saturn accelerator into a single disk feed. Experiments with a high impedance electron beam load operating at twice the self-limited impedance of the CSMITL confirm key design features and demonstrate robust operation. © 2011 IEEE.

Digest of Technical Papers-IEEE International Pulsed Power Conference

Hjalmarson, Harold P.; Pineda, A.C.; Jorgenson, Roy E.; Pasik, Michael F.

Continuum calculations are used to understand the avalanche growth of electrical current in a composite insulator consisting of an air gap and a solid dielectic. The results show that trapped charge can quench the electrical breakdown. The results are compared with phenomena found in dielectric barrier discharge (DBD) devices. © 2011 IEEE.

Turner, C.D.; Pasik, Michael F.; Seidel, David B.

The Unstructured Time-Domain ElectroMagnetics (UTDEM) portion of the EMPHASIS suite solves Maxwell's equations using finite-element techniques on unstructured meshes. This document provides user-specific information to facilitate the use of the code for applications of interest. UTDEM is a general-purpose code for solving Maxwell's equations on arbitrary, unstructured tetrahedral meshes. The geometries and the meshes thereof are limited only by the patience of the user in meshing and by the available computing resources for the solution. UTDEM solves Maxwell's equations using finite-element method (FEM) techniques on tetrahedral elements using vector, edge-conforming basis functions. EMPHASIS/Nevada Unstructured Time-Domain ElectroMagnetic Particle-In-Cell (UTDEM PIC) is a superset of the capabilities found in UTDEM. It adds the capability to simulate systems in which the effects of free charge are important and need to be treated in a self-consistent manner. This is done by integrating the equations of motion for macroparticles (a macroparticle is an object that represents a large number of real physical particles, all with the same position and momentum) being accelerated by the electromagnetic forces upon the particle (Lorentz force). The motion of these particles results in a current, which is a source for the fields in Maxwell's equations.

Langston, William L.; Pasik, Michael F.; Coats, Rebecca S.; Pointon, Timothy D.; Seidel, David B.; McKee, George R.; Schneider, Larry X.

Abstract not provided.

Hjalmarson, Harold P.; Pasik, Michael F.; Jorgenson, Roy E.

Abstract not provided.

Pasik, Michael F.; Coats, Rebecca S.; Ulrickson, M.A.

Abstract not provided.

Fusion Science and Technology

Coats, Rebecca S.; Pasik, Michael F.; Ulrickson, M.A.

Abstract not provided.

Physical Review Special Topics in Accelerators and Beams

Langston, William L.; Pasik, Michael F.; Coats, Rebecca S.; Pointon, Timothy D.; Seidel, David B.; McKee, George R.; Schneider, Larry X.

Abstract not provided.

Coats, Rebecca S.; Pasik, Michael F.; Ulrickson, M.A.

Abstract not provided.

IEEE Transactions on Plasma Science

Kotulski, Joseph D.; Coats, Rebecca S.; Pasik, Michael F.; Ulrickson, M.A.

An electromagnetic analysis is performed on the ITER shield modules under different plasma-disruption scenarios using the OPERA-3d software. The models considered include the baseline design as provided by the International Organization and an enhanced design that includes the more realistic geometrical features of a shield module. The modeling procedure is explained, electromagnetic torques are presented, and results of the modeling are discussed. © 2010 IEEE.

Proceedings - Symposium on Fusion Engineering

Kotulski, J.D.; Coats, Rebecca S.; Pasik, Michael F.; Ulrickson, M.A.; Garde, J.

An electromagnetic analysis is performed on different first wall designs for the ITER device. The electromagnetic forces and torques present due to a plasma disruption event are calculated and compared for the different designs.

Proceedings - Symposium on Fusion Engineering

Kotulski, J.D.; Coats, Rebecca S.; Pasik, Michael F.; Ulrickson, M.A.

An electromagnetic analysis is performed on the ITER shield modules under different plasma disruption scenarios using the OPERA-3d software. The modeling procedure is explained, electromagnetic torques are presented, and results of the modeling are discussed.

Fusion Engineering and Design

Kotulski, J.D.; Coats, Rebecca S.; Pasik, Michael F.

This paper describes the eddy current computation and the resultant forces and torques on selected shield modules assigned to the US team that occur due to plasma disruption. The plasma disruption considered is referred to as major disruption (MD) and is one of the disruption cases defined by the International Organization (IO). This paper identifies the applicability of geometrical simplifications for future design analyses. In particular it is shown that cutting a module in half does not preserve the physics of the eddy current generation and resultant calculations while modeling a full module including the nearest modules does preserve the fundamental physics. The force results are shown for shield modules 7 and 13 exposing the validity of geometrical simplifications. The computed torque for these two modules is also presented. © 2008 Elsevier B.V.

Struve, Kenneth W.; Bennett, Lawrence F.; Davis, Jean-Paul D.; Harjes, Henry C.; Pasik, Michael F.; Savage, Mark E.; Stygar, William A.

Abstract not provided.

Digest of Technical Papers-IEEE International Pulsed Power Conference

Pasik, Michael F.; Coats, Rebecca S.; Johnson, William Arthur.; Elizondo-Decanini, Juan M.; Pointon, Timothy D.; Turner, C.D.; Bohnhoff, William J.; Lehr, J.M.; Savage, Mark E.

The ZR accelerator is a refurbishment of Sandia National Laboratories Z accelerator [1]. The ZR accelerator components were designed using electrostatic and circuit modeling tools. Transient electromagnetic modeling has played a complementary role in the analysis of ZR components [2]. In this paper we describe a 3D transient electromagnetic analysis of the ZR water convolute and stack using edge-based finite element techniques. © 2005 IEEE.

Proceedings - Symposium on Fusion Engineering

Kotulski, J.D.; Coats, Rebecca S.; Pasik, Michael F.

This paper describes the electromagnetic analysis that has been completed using the OPERA-3d product to characterize the folces on the ITER shield modules as part of the conceptual design. These forces exist due to the interaction of the eddy currents induced in the shield modules and the large magnetic fields present in the tokamak. ©2007 IEEE.