Publications

Glover, Steven F.; Rudys, Joseph M.; Sceiford, Matthew S.; Warne, Larry K.; Coats, Rebecca S.; Johnson, William Arthur.; Davis, Jean-Paul D.; Schneider, Larry X.; Reed, Kim W.; Pena, Gary P.; Hall, Clint A.; Hickman, Randy J.; Lehr, J.M.; McDaniel, Dillon H.

Abstract not provided.

Johnson, William Arthur.; Warne, Larry K.; Basilio, Lorena I.; Langston, William L.; Sinclair, Michael B.

Abstract not provided.

Johnson, William Arthur.; Basilio, Lorena I.; Langston, William L.

Abstract not provided.

Langston, William L.; Warne, Larry K.; Johnson, William Arthur.; Sinclair, Michael B.; Basilio, Lorena I.

Abstract not provided.

Johnson, William Arthur.

Abstract not provided.

Johnson, William Arthur.

In this paper an approach is described for the efficient computation of the mixed-potential scalar and dyadic Green's functions for a one-dimensional periodic (periodic along x direction) array of point sources embedded in a planar stratified structure. Suitable asymptotic extractions are performed on the slowly converging spectral series. The extracted terms are summed back through the Ewald method, modified and optimized to efficiently deal with all the different terms. The accelerated Green's functions allow for complex wavenumbers, and are thus suitable for application to leaky-wave antennas analysis. Suitable choices of the spectral integration paths are made in order to account for leakage effects and the proper/improper nature of the various space harmonics that form the 1-D periodic Green's function.

Warne, Larry K.; Johnson, William Arthur.; Langston, William L.; Sinclair, Michael B.

This paper introduces an effective-media toolset that can be used for the design of metamaterial structures based on metallic components such as split-ring resonators and dipoles, as well as dielectric spherical resonators. For demonstration purposes the toolset will be used to generate infrared metamaterial designs, and the predicted performances will be verified with full-wave numerical simulations.

IEEE Transatcions on Antennas and Propagation

Johnson, William Arthur.

Abstract not provided.

IEEE Antennas and Wireless Propagation Letters

Basilio, Lorena I.; Warne, Larry K.; Johnson, William Arthur.; Langston, William L.; Sinclair, Michael B.

Abstract not provided.

Johnson, William Arthur.

Abstract not provided.

Davids, Paul D.; Cruz-Cabrera, A.A.; Basilio, Lorena I.; Wendt, J.R.; Kemme, S.A.; Johnson, William Arthur.; Loui, Hung L.

Plasmonic structures open up new opportunities in photonic devices, sometimes offering an alternate method to perform a function and sometimes offering capabilities not possible with standard optics. In this LDRD we successfully demonstrated metal coatings on optical surfaces that do not adversely affect the transmission of those surfaces at the design frequency. This technology could be applied as an RF noise blocking layer across an optical aperture or as a method to apply an electric field to an active electro-optic device without affecting optical performance. We also demonstrated thin optical absorbers using similar patterned surfaces. These infrared optical antennas show promise as a method to improve performance in mercury cadmium telluride detectors. Furthermore, these structures could be coupled with other components to lead to direct rectification of infrared radiation. This possibility leads to a new method for infrared detection and energy harvesting of infrared radiation.

Basilio, Lorena I.; Johnson, William Arthur.; Warne, Larry K.; Langston, William L.; Peters, D.W.; Sinclair, Michael B.

Abstract not provided.

Johnson, William Arthur.; Basilio, Lorena I.; Mehlhorn, Thomas A.; Flicker, Dawn G.

Abstract not provided.

Basilio, Lorena I.; Johnson, William Arthur.; Cruz-Cabrera, A.A.; Wendt, J.R.; Kemme, S.A.

Abstract not provided.

Basilio, Lorena I.; Johnson, William Arthur.; Cruz-Cabrera, A.A.; Wendt, J.R.; Kemme, S.A.

Abstract not provided.

Warne, Larry K.; Merewether, Kimball O.; Johnson, William Arthur.

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.

Johnson, William Arthur.; Basilio, Lorena I.; Kotulski, J.D.; Jorgenson, Roy E.; Warne, Larry K.; Coats, Rebecca S.; Langston, William L.

Abstract not provided.

Johnson, William Arthur.; Coats, Rebecca S.; Jorgenson, Roy E.; Hebner, Gregory A.

This report constructs simple circuit models for a hairpin shaped resonant plasma probe. Effects of the plasma sheath region surrounding the wires making up the probe are determined. Electromagnetic simulations of the probe are compared to the circuit model results. The perturbing effects of the disc cavity in which the probe operates are also found.

Warne, Larry K.; Johnson, William Arthur.; Chen, Kenneth C.; Merewether, Kimball O.

Simple formulas are given for the interior voltages appearing across bolted joints from exterior lightning currents. External slot and bolt inductances as well as internal slot and bolt diffusion effects are included. Both linear and ferromagnetic wall materials are considered. A useful simplification of the slot current distribution into linear stripline and cylindrical parts (near the bolts) allows the nonlinear voltages to be estimated in closed form.

Johnson, William Arthur.

Abstract not provided.

Jorgenson, Roy E.; Basilio, Lorena I.; Johnson, William Arthur.; Warne, Larry K.; Peters, D.W.

In this LDRD we examine techniques to analyze the electromagnetic scattering from structures that are nearly periodic. Nearly periodic could mean that one of the structure's unit cells is different from all the others--a defect. It could also mean that the structure is truncated, or butted up against another periodic structure to form a seam. Straightforward electromagnetic analysis of these nearly periodic structures requires us to grid the entire structure, which would overwhelm today's computers and the computers in the foreseeable future. In this report we will examine various approximations that allow us to continue to exploit some aspects of the structure's periodicity and thereby reduce the number of unknowns required for analysis. We will use the Green's Function Interpolation with a Fast Fourier Transform (GIFFT) to examine isolated defects both in the form of a source dipole over a meta-material slab and as a rotated dipole in a finite array of dipoles. We will look at the numerically exact solution of a one-dimensional seam. In order to solve a two-dimensional seam, we formulate an efficient way to calculate the Green's function of a 1d array of point sources. We next formulate ways of calculating the far-field due to a seam and due to array truncation based on both array theory and high-frequency asymptotic methods. We compare the high-frequency and GIFFT results. Finally, we use GIFFT to solve a simple, two-dimensional seam problem.

Proposed for publication in Physical Review E.

Stygar, William A.; Leeper, Ramon J.; Mazarakis, Michael G.; McDaniel, Dillon H.; Mckenney, John M.; Mills, Jerry A.; Ruggles, Larry R.; Seamen, Johann F.; Simpson, Walter W.; Dropinski, Steven D.; Warne, Larry K.; York, Matthew W.; McGurn, John S.; Bryce, Edwin A.; Chandler, Gordon A.; Cuneo, M.E.; Johnson, William Arthur.; Jorgenson, Roy E.

We have developed a diagnostic system that measures the spectrally integrated (i.e. the total) energy and power radiated by a pulsed blackbody x-ray source. The total-energy-and-power (TEP) diagnostic system is optimized for blackbody temperatures between 50 and 350 eV. The system can view apertured sources that radiate energies and powers as high as 2 MJ and 200 TW, respectively, and has been successfully tested at 0.84 MJ and 73 TW on the Z pulsed-power accelerator. The TEP system consists of two pinhole arrays, two silicon-diode detectors, and two thin-film nickel bolometers. Each of the two pinhole arrays is paired with a single silicon diode. Each array consists of a 38 x 38 square array of 10-{micro}m-diameter pinholes in a 50-{micro}m-thick tantalum plate. The arrays achromatically attenuate the x-ray flux by a factor of {approx}1800. The use of such arrays for the attenuation of soft x rays was first proposed by Turner and co-workers [Rev. Sci. Instrum. 70, 656 (1999)RSINAK0034-674810.1063/1.1149385]. The attenuated flux from each array illuminates its associated diode; the diode's output current is recorded by a data-acquisition system with 0.6-ns time resolution. The arrays and diodes are located 19 and 24 m from the source, respectively. Because the diodes are designed to have an approximately flat spectral sensitivity, the output current from each diode is proportional to the x-ray power. The nickel bolometers are fielded at a slightly different angle from the array-diode combinations, and view (without pinhole attenuation) the same x-ray source. The bolometers measure the total x-ray energy radiated by the source and--on every shot--provide an in situ calibration of the array-diode combinations. Two array-diode pairs and two bolometers are fielded to reduce random uncertainties. An analytic model (which accounts for pinhole-diffraction effects) of the sensitivity of an array-diode combination is presented.

ICEAA 2005 - 9th International Conference on Electromagnetics in Advanced Applications and EESC 2005 - 11th European Electromagnetic Structures Conference

Basilio, L.I.; Johnson, William Arthur.; Jackson, D.R.; Wilton, D.R.

Simulation results demonstrating transmission enhancement through a sub-wavelength aperature in an infinite plasmon array are presented. The results are obtained using EIGER and are considered preliminary before proceeding to the simulation of finite-plasmon arrays.

Johnson, William Arthur.; Warne, Larry K.; Basilio, Lorena I.; Kotulski, J.D.; Coats, Rebecca S.; Jorgenson, Roy E.

Abstract not provided.