Publications

As part of the Strategic Petroleum Reserve (SPR), the Weeks Island oil storage site is a converted salt mine that contains approximately 73 million barrels of oil overlying 0.5 million barrels of brine. The oil is contained on two levels of the converted mine which are connected by a number of shafts and openings. Oil recycle exercises are periodically conducted to test the oil fill and withdrawal systems in which oil is simultaneously injected and withdrawn from two different locations in the lower level, and brine may be transported around the lower level of the mine by the movement of the oil. 11 refs., 16 figs.

An expert system developed to provide assistance to those involved with the creation, modification, interpretation and maintenance of Sandia's Engineering Procedures is described. 6 refs., 2 figs.

The Engineering Graphics System (EGS) is a computer program for use on Digital Equipment Corporation VAXstation color workstations. Its purpose is to manage and plot sets of engineering analysis data for use in reports and presentations. It is capable of producing nearly any type of x-y plot from a set of tabulated data. After the plot curves have been retrieved from the tabulated data, EGS can be used to interactively modify the appearance of the plot for use in a report or presentation. Modifications appear on the workstation display exactly as they appear on final hardcopy, which avoids costly iterations. Hardcopy plots can be made on two different black and white laser printers and on two different color printers, and plots can be converted for use by the Interleaf technical publishing software. 222 figs.

Power deposition measurements have been carried out on the ALT-II toroidal belt pump limiter and the inner bumper limiter in TEXTOR for Ohmic, neutral beam and RF heated discharges. Two infrared cameras and the ALT-II thermocouple array indicate that {lambda}{sub E} remains unchanged (7 mm) in the presence of beams but increases to 10 mm with ICRH. The heating distribution is less uniform on the bumper limiter than on ALT-II, which potentially could explain the differences seen in graphite surface pumping. 9 refs., 3 figs., 1 tab.

The operation of TORE SUPRA at full power (25MW, 30s) has led to the design of a full set of actively pumped carbon limiters to remove at least 8MW and to partially control the particle balance. An interim version is now installed, composed of 5 vertical and one horizontal outboard (OPL) pump limiters, semi-inertially water cooled. The latter is a result of a collaboration between the US DOE and the Association EUR-CEA, it is fully instrumented and therefore can serve as a reference for the final design. Ohmic discharges (1.85T, 740kA, 8.5s) in helium have been used to test the thermal load on and the particle exhaust efficiency of the OPL. In these experiments the plasma is formed on the inner wall (R = 232 cm, a = 76 cm) and subsequently displaced (6 cm) outward, early on the current plateau, to lean on the OPL (R = 238 cm, a = 75 cm). In addition to the limiters above, a non-pumped outboard (ONLP) limiter of identical shape to the OPL served to produce similar discharges for better comparison and determination of particle control. A comparison is made hereafter of the thermal load and particle pumping effects on the OPL when the plasma is in contact either with the OPL/ONPL alone or with the OPL and the vertical limiters together. 3 refs., 1 fig., 2 tabs.

Particle collection, removal, and exhaust by the toroidal belt pump limiter ALT-III have been measured in deuterium discharges with co-, counter-, and balanced injection of 48 keV neutral hydrogen particles. Particle collection increases from 50-80 A to 150-320 A during 1.2 MW of co- or counter-injection or 2.4 MW of balanced injection. The removal rate for pumping at two of the eight blades (3 of 15 scoops) reaches 2.7 Torr-l/s with a removal efficiency of nearly 45%. Extrapolating these results to a full belt with 15 scoops and eight pumps yields 140 amps of removal. This compares favorably with the maximum injectable current of 50 A and suggests that ALT-II with full pumping can provide sufficient exhaust during NI heating. 4 figs.

The microstructure and mechanical properties of high purity aluminum implanted with 20 at. % oxygen to a depth of roughly 500 nm and subjected to various thermal histories have been examined. Transmission electron microscopy and Rutherford-backscattering spectrometry were used to characterize the depth and nature of the implanted zone. As implanted, the material appears to contain a homogeneous distribution of disordered precipitates with sizes of 1.5-3.5 nm. Annealing at 450 or 550{degree}C/1 hr induces ordering of the precipitates but only causes slight coarsening. Ultra-low load identation hardness testing was used to probe the mechanical response of the surface-modified material. The data from the hardness tests were interpreted through the use of a finite-element model; the results indicate the flow stresses of an implanted and annealed layer are as high as 1600 MPa. The as-implanted material is much harder, approaching 3300 MPa. The degree of strengthening expected for the as-implanted and post-annealed material on the basis of the observed microstructure was estimated using several micromechanical models, and the results conform to the findings from indentation testing. 9 refs., 5 figs.

It has been observed on TEXTOR that in low density discharges the electrons gain enough energy to emit relativistic synchrotron radiation in the 3--6 {mu}m IR-range, and this radiation is due to electrons with energies up to 30 MeV. The momentum in perpendicular direction amounts to about 1/10 of the longitudinal one. The total number of runaways is of the order of 10{sup 16} electrons, and they carry a current of about 20% of the total plasma current. 3 refs., 1 fig.

The surface properties of symmetric microphase separated diblock copolymers of polystyrene (PS) and polymethylmethacrylate (PMMA) were investigated using X-ray photoelectron spectroscopy (XPS), the specular reflectivity of neutrons and secondary ion mass spectrometry (SIMS). PS, the lower surface energy component, exhibited a preferential affinity for the free surface. For copolymers that are far from the bulk microphase separation transition (MST), the surface consists of a layer of pure PS. When the system is close to the MST the surface is a mixture of PS and PMMA. The PS surface excess can be described by a N-{sup 1/2} dependence, where N is the number if segments that comprise the copolymer chain. It is shown that the surface undergoes an ordering transition at a temperature T{sub s} that is above that of the bulk MST. The ordering of the bulk lamellar morphology is induced by an ordering at the surface. This is analogous to the ferromagnetic order observed in systems such as Gd at temperatures above the bulk Curie temperature. The results here are discussed in light of previous work on copolymer surfaces and in light of mean field theory. 31 refs., 8 figs.

Oxygen ion beam bombardment has been studied as a means for incorporating oxygen into thin films of Y-Ba-Cu-oxide either by enhancing the transport of oxygen to substrates during ion-beam sputtering, or by direct incorporation of oxygen by ion-assisted deposition. Optical emission spectroscopy was used to study the ion-beam bombardment of bulk superconducting targets as the oxygen content of the ion beam was varied between 0% (pure argon) and 100% oxygen. This showed that oxygen did not directly combine with metallic elements in the target to increase the oxygen content of the stream of particles moving toward the substrate. The oxygen content of the sputter beam did, however, change the relative emission intensity from the various target components. Addition of a second ion beam directing an oxygen beam toward the substrate as the film is grown, caused large variations in the stoichiometry of the deposited films. At low ion currents, no increase in the oxygen content of the films was detected, while at relatively high currents, the oxygen incorporation increased. However, the sputtering of the metallic components of the film increased, leading to very low growth rates. 8 refs., 5 figs.

Intense beams of light ions are being developed at Sandia National Laboratories as a promising driver option for Inertial Confinement Fusion (ICF) implosions. The Particle Beam Fusion Accelerator II (PBFA II) will provide the physics basis for light-ion-beam driven ICF targets. Recent progress made in ion beam generation focusing on PBFA II has led to a record 5.4 TW/cm{sup 2} peak focal intensity with {gt}80 kJ proton energy delivered to a 6-mm diameter sphere. The driver-development program on PBFA II is reviewed. A design concept for a light ion beam driver for the Laboratory Microfusion Facility is also presented. 34 refs., 9 figs., 1 tab.

In an earlier paper, we reported that it is possible to train a first-order multi-layer feedforward network with backpropagation to classify raw 8-bit images of vehicles. We concluded that a linear feedforward network is capable of within-class generalization when trained with perspective views taken every 10{degree}, but it is incapable of one-class generalization. This paper describes the results of a set of experiments to train a feedforward network with second-order inputs to perform one-class classification on image data. We compare the results of the first-order network and the second-order network and show that the second order network is better able to generalize as a one-class classifier. 7 refs., 6 figs.

Short communication.

Ion beam studies on radiation enhanced sublimation (RES) have shown that above 800{degree} C energetic ions incident on graphite produce erosion in the form of carbon atoms with thermal energies and that the erosion rate rises roughly exponentially with temperature. Until recently, the question remained whether RES would scale linearly with flux over three to four orders of magnitude to the plasma edge fluxes in CIT and ITER, where the predicted erosion rates would severely limit the designs for plasma-facing components. Also, RES and carbon self-sputtering may also be involved in the carbon blooms'' observed in TFTR and JET. The data reported here from PISCES, a plasma source at UCLA, are the first RES data at fluxes approaching the plasma edge conditions in a large tokamak and they show little reduction from a direct linear dependence upon flux. Erosion rates measured by weight loss are reported for POCO graphite exposed to helium plasmas for a temperature range from 900--2000{degree} C, ion energies of 30--300 eV, ion fluxes of 1--6 {times} 10{sup 18} cm{sup {minus}2} s{sup {minus}1}, densities of 2--10 {times} 10{sup 12} cm{sup {minus}3} and electron temperatures of 4-10 eV. For these conditions, the amount of redeposition and carbon self-sputtering was minimal. Over 1700{degree} C, there is evidence of electron emission from the sample. 26 refs., 4 figs., 1 tabs.

Silicon power diodes, transistors, thyristors and other devices can be damaged by elevated temperatures, temperature cycling, and radiation. In this paper we discuss the vulnerability of devices that integrate bipolar and MOSFET (metal-oxide-semiconductor-field-effect transistor) devices onto a single chip. Such devices offer the advantages of good current carrying capability that is characteristic of bipolar structures and high impedance control nodes that are characteristic of MOSFET devices. Devices located near a space-based fission power source will be subjected to high temperatures, temperature cycling, naturally occurring radiation, radiation from the reactor; and these devices may be subjected to radiation from or caused by weapons used to attack the power source. Damaging radiation includes electrons and protons trapped in naturally occurring radiation belts, electrons pumped into these belts as a result of nuclear explosions, cosmic rays, neutrons from the reactor, and high energy photons (gamma rays and x-rays). 3 refs., 2 figs.

We consider problems related to the computation of Hermite and Smith normal forms of integer matrices, and more generally matrices over a principal ideal ring. First, we show that if the matrix A is m {times} n, with rank m and integer entries bounded in absolute value by T, then the Hermite normal form can be computed in O(m{sup 2}nB(m log(mT))) bit operations, where B(t) denotes a function that bounds the time required to perform the extended Euclidean algorithm on two t bit integers. Furthermore we show that the Smith normal form can be computed in O(m{sup 3}nB(m log(mT))log(mT)) bit operations. In the second part of the paper we apply fast matrix multiplication techniques to the problem of triangularizing a matrix over a ring using elementary column operations. We also prove that matrix inversion and multiplication are equivalent in complexity over an arbitrary Principal Ideal Domain, generalizing a result of Bunch and Hopcroft. We then apply our general results to obtain an algorithm for triangularizing integer matrices that has a faster running timer than the known Hermite normal form algorithms. The triangular matrix that is computed has small entries like the Hermite normal form, and will suffice for many applications. In the last part of the paper, we discuss a probabilistic method for calculating Smith normal forms. 17 refs.

We have examined several crystals belonging to the Tl-2122 structure type (Tl{sub 2}CaBa{sub 2}Cu{sub 2}O{sub 8} with c = 29{angstrom}), and have shown that cation solid solution occurs. Such cation disorder appears to be responsible for the observed small differences in lattice parameters reported by various investigators and to contribute towards the substantial variation in the superconducting transition temperatures. 10 refs., 2 tabs.

Nuclear power plants present the fire protection community with unique challenges. In addition to the traditional concerns of life safety and property loss prevention, nuclear safety analysts must also be concerned with the impact of fires on the safe operability of the nuclear reactor. Safe shutdown equipment must be protected from fire damage. When nuclear power plants were first designed and built, fire safety considerations were based primarily on the same criteria applied to general industrial facilities, primarily those concerning life safety and property loss prevention. This practice continued until 1975 when the Brown's Ferry nuclear reactor site experienced a severe cable tray fire. The fire burned for over seven hours, due in part to the reluctance of on-site personnel to use water on the fire for fear of shorting out critical electrical circuits. 4 figs.

The radiation spectrum constituents of interest to microelectronics are prompt gamma or x-ray, total dose, neutrons (or protons), and cosmic radiation. Each of these constituents has a unique effect upon microelectronic components and requires unique techniques to improve the microelectronic radiation tolerance to such an exposure. This paper reviews the radiation effects associated with the natural space and nuclear reactor radiation environment, that is to say, total dose, neutrons, and cosmic rays. 2 refs., 6 figs.

Shock-induced reaction synthesis (SRS) is used for solid state processing of Ni-Al, Ni-Si, and Nb-Si type compounds, starting with elemental powder mixtures. The constituent elemental powders are blended in different stoichiometries and packed at 65% density in stainless steel capsules. A steel flyer plate, accelerated by the detonation of an explosive, impacts the powder containing capsules embedded in a steel recovery fixture backed by a momentum trap. The shock wave generated upon impact triggers a self-sustaining, exothermic reaction between the elemental powder constituents, thereby synthesizing the compound and at the same time consolidating the porous mass into 12mm diameter by 5mm thick compacts. The characteristics of the SRS technique and the structural features of the shock synthesized products will be discussed. 18 refs., 11 figs.

Preliminary BUCKSHOT simulations of a recirculating linear accelerator have been made. Two accelerator configurations have been examined for a variety of beam currents (10-40 kA). The first configuration is an attempt to simulate conditions accessible to near-term experiments. The second configuration tries to mock up a next generation application type machine. 3 figs.

Hypervelocity launchers are used to study the high-pressure equation of state of materials in regimes inaccessible by other methods. Two-stage light gas guns have been extremely useful for these applications, but have a practical velocity limit of about 8--9 km/s for impact studies. In this paper, we describe a three-stage launcher consisting of a two-stage light gas gun combined with a third-stage railgun, which overcomes previous velocity limitations pertaining to two-stage guns. This launcher is being developed for operation to 15 km/s and has achieved projectile velocities of 7.2 km/s to date. 10 refs., 9 figs., 1 tab.

The in-plane linear elastic constants of woven fabric are determined in terms of the specific fabric microstructure. The fabric is assumed to be a spatially periodic interlaced network of orthogonal yarns and the individual yarns are modeled as extensible elastica. These results indicate that a significant coupling of bending and stretching effects occurs during deformation. Results of this theoretical analysis compare favorable with measured in-plane elastic constants for Vincel yarn fabrics. 17 refs., 2 figs., 1 tab.

The utility of the magnetically insulated transmission line oscillator (MILO) as a high power microwave source depends on how efficiently power can be extracted from it. We have designed a slow-wave stepped transformer for the purpose of axially extracting microwave power from a 3.6 GHz coaxial MILO. The slow-wave transformer design was optimized using particle-in-cell simulation, and tested in experiments performed on the HPM Simulation Division's GEMINI and GYPSY water Blumlein pulse power sources. In this paper we summarize the slow-wave stepped transformer design, and describe MILO axial power extraction experiments which yielded up to 300 MW of radiated power. 10 refs., 4 figs., 2 tabs.

This presentation is a case study of the system that was developed to move data between our mainframe HRIS and the REGISTRAR. It not only contains a description of the system itself but of the factors that come into play in deciding whether to implement a system at all and in deciding what kind of system to implement.

Heavy particle radiation can produce upsets in digital circuits as well as trigger burn out or breakdown in power MOSFETs and MNOS nonvolatile memories. Latch-up may also be stimulated by heavy ions. This report covers work done on the effects of heavy particle radiation on PN junctions, CMOS inverters, CMOS latch, MOSFET and non-volatile memories. 15 refs., 3 figs.

In this study, we explored several ways of extending SP-100 reactor technology to higher power levels. One approach was to use the reference SP-100 pin design and increase the fuel pin length and the number of fuel pins as needed to provide higher capability. The impact on scaling of a modified and advanced SP-100 reactor technology was also explored. Finally, the effect of using alternative power conversion subsystems, with SP-100 reactor technology was investigated. One of the principal concerns for any space-based system is mass; consequently, this study focused on estimating reactor, shield, and total system mass. The RSMASS code (Marshall 1986) was used to estimate reactor and shield mass. Simple algorithms developed at NASA Lewis Research Center were used to estimate the balance of system mass. Power ranges from 100 kWe to 10 MWe were explored assuming both one year and seven years of operation. Thermoelectric, Stirling, Rankine, and Brayton power conversion systems were investigated. The impact on safety, reliability, and other system attributes, caused by extending the technology to higher power levels, was also investigated. 6 refs., 4 figs., 3 tabs.

Outlier samples can have very detrimental effects on the performances of multivariate calibration methods, as these methods are generally not very robust. Often, the software implementations of these methods do not check for outliers. If outliers are not detected, invalid predictions may result. This paper illustrates some simple exploratory procedures for detecting outliers with examples from near-infrared and mid-infrared spectroscopy using partial least-squares regression as the calibration method. 8 refs., 9 figs., 1 tab.

The experiments described here indicate when one of Nature's best fractals -- the Brownian trail -- becomes nonfractal. In most ambient fluids, the trail of a Brownian particle is self-similar over many decades of length. For example, the trail of a submicron particle suspended in an ordinary liquid, recorded at equal time intervals, exhibits apparently discontinuous changes in velocity from macroscopic lengths down to molecular lengths: the trail is a random walk with no velocity memory'' from one step to the next. In ideal Brownian motion, the kinks in the trail persist to infinitesimal time intervals, i.e., it is a curve without tangents. Even in real Brownian motion in a liquid, the time interval must be shortened to {approximately}10{sup {minus}8}s before the velocity appears continuous. In sufficiently rarefied environments, this time resolution at which a Brownian trail is rectified from a curve without tangents to a smoothly varying trajectory is greatly lengthened, making it possible to study the kinetic regime by dynamic light scattering. Our recent experiments with particles in a plasma have demonstrated this capability. In this regime, the particle velocity persists over a finite step length'' allowing an analogy to an ideal gas with Maxwell-Boltzmann velocities; the particle mass could be obtained from equipartition. The crossover from ballistic flight to hydrodynamic diffusion was also seen. 8 refs., 1 fig.

The MELCOR computer code, which has been developed at Sandia National Laboratories for the US Nuclear Regulatory Commission as a tool for calculating realistic estimates of severe accident consequences and source terms, has been used to analyze a series of containment issues for station blackout sequences for the Grand Gulf Nuclear Power Plant. The results indicate that there is a limited time interval in which the drywell atmosphere would be flammable, and that this would only occur if the vacuum breaker were to stick open within a narrow time window. If burning does occur during this time, it appears quite likely that it would not pose a threat to the drywell wall. The main conclusion from this study is that the drywell atmosphere is not very likely to be flammable for a station blackout sequence. 1 ref. (S.J.)

The influence of postweld heat treatment (PWHT) on the structure, mechanical properties and fracture characteristics of pulsed, Nd: YAG laser welds in a Ti-14.8 wt % Al-21.3 wt % Nb titanium aluminide has been investigated. Significant microstructure variations within the fusion zone (FZ) of all heat-treated welds were attributed primarily to the influence of local compositional fluctuations on decomposition of the metastable-{beta} microstructure present in the as-welded FZ. An increase in PWHT temperature promoted a decrease in the maximum FZ hardness and an increase in the longitudinal-weld bend ductility. Correspondingly, the proportion of ductile tearing to cleavage fracture within the FZ increased with an increase in PWHT temperature. 8 refs., 6 figs.

A matched chirp transform (MCT) method for detecting a dispersive electromagnetic pulse is described. The unique feature of this transform is that it gives a distribution of signal amplitude over time rather than frequency, thereby simplifying signal detection and identification in the case described here. In the MCT method, the incoming signal is matched to a set of signal segments that chirp in accordance with an expected model of the dispersive medium. The performance of the MCT method is compared to that of a standard periodogram method of frequency measurement.

In previous RADLAC-II beam propagation experiments, stable propagation over a Nordsieck length, in full pressure Albuquerque air (p {approximately}640 Torr) was observed. In these experiments, high transverse momentum resulted in a large equilibrium radius and thus a long betatron wavelength. Following the completion of the RADLAC-II upgrade, a new set of experiments with a small diameter (d {approximately}2 cm), high current (I {approximately}40 kA), low transverse momentum ({beta}{perpendicular} {approximately}0.2) should be possible. The development of time-resolved diagnostics, data analysis codes, and the formulation of output from theoretical calculations in a format as seen by these diagnostics in the lab continues to be a major source of effort in the program. 2 figs.

The final link in the High-Power Microwave (HPM) coupling chain is the distribution of energy on printed-circuit (pc) boards. This distribution is a critical part of the total problem, because the bottom line for damage or upset is what occurs at the component level. Like ports-of-entry (POE's), board coupling paths have their own transfer functions. Since most pc boards are not designed to operate at microwave frequencies, these transfer functions can be very complicated. In addition, active elements on the board are likely to make this part of the problem non-linear. 3 refs., 5 figs.

This paper reports the changes caused by fast neutrons and 200 MeV protons in the electrical properties of high electron mobility transistors (HEMT). A larger gate voltage was required after irradiation with neutron fluences in the 1E14 to 2E15 n/cm{sup 2} range and 200 MeV proton fluences in the 1E14 to 1E15 p/cm{sup 2} range than was required prior to irradiation to obtain the same value of I{sub ds}. The increase in gate voltage required to compensate for a fluence of 1E15 protons/cm{sup 2} was up to four times as great as that required to compensate for the same fluence of neutrons. All devices showed microwave gain (s21) after exposure to 6E14 particles/cm{sup 2} if the gate bias was adjusted to maintain the pre-irradiation value of I{sub ds}. Gamma irradiation at 5E7 rads(GaAs) had no detectable effect on the devices. 8 refs., 6 figs., 1 tab.

Concerns about low-{gamma} relativistic electron beams (REB) being initially injected into the RLA and about energy spreads due to degradation of the accelerating cavity repeating pulse shapes have resulted in our designing a new 4-MV, 20-kA injector, improving the 24-switch trigger system for the ET-2 cavity, and identifying critical factors in the cavity design that affect the pulse shape. We summarize the Metglas inductively isolated, stacked cavity injector design and report on the improvements (completed and proposed) for the ET-2 cavity pulsed power. 7 refs., 6 figs.

Three prototype zinc/bromine batteries were evaluated a Sandia during the last year. The objectives of these tests were to determine performance, cycle life, durability of the auxiliary components, and failure mechanisms. All three were deliverables from a Sandia development contract with Energy Research Corporation (ERC). The test results were communicated to ERC along with suggestions for improving battery design and reliability. 3 figs., 2 tabs.

Zinc/bromine flow batteries are being developed for vehicular and utility load leveling applications by Johnson Controls Co. and Energy Research Corp. under DOE sponsorship. Problems that have been encountered with the zinc/bromine battery are loss of coulombic efficiency brought about by permeation of bromine through the separator and limited life caused by attack of the bromine-containing electrolyte on plastic parts, particularly the flow frame. In this paper, we show that large decreases in the bromine transport rates through microporous separators can be achieved with only a minimal loss of conductivity and identify a chemically stable replacement for PVC, a flowframe material. 4 figs., 1 tab.

The working group on electrical breakdown in vacuum was charged with considering all possible mechanisms by which electrical breakdown might occur either through the vacuum or along insulator bushings in large area electron beam emitter assemblies. It was understood that present systems need to be scaled up, by an order of magnitude or more in both beam area and total energy, to meet demands for higher power and larger size machines, and that increases in the e-beam current density and transport efficiency are also sought. A consideration of the consequences of such a scale-up was pertinent to many of the topics listed in the working-group agenda. Our group attempted to address each of these topics. 18 refs.

Whenever a new elastomer is formulated or an old formulation is modified, it is important to estimate the material's anticipated lifetime in various use environments. For extended lifetimes (years) this often requires the application of accelerated aging techniques which typically involve the modelling of results obtained at higher-than-ambient environmental stress levels. For many practical applications of elastomers, air is present during environmental exposures -- this usually implies that important oxidation effects underly the degradation of the material. Unfortunately, exposure of elastomers to air during aging often results in inhomogeneously oxidized samples, a complication which impacts attempts both to understand the oxidation process and to extrapolate accelerated exposures to long-term conditions. As has been clear for many years, in order to confidently extrapolate shorter-term accelerated simulations to long-term, air-aging conditions, one must be able to monitor and quantitatively understand diffusion-limited oxidation effects. In this review we will highlight some of the recent developments in both experimental techniques and theoretical modelling of relevance to this goal. 28 refs., 12 figs.

The discrete ordinates (S{sub N}) method, first developed for stellar atmospheres, has been used extensively on various other radiation transport problems. In reactor analysis the method is generally used to generate parameters for design models based on more approximate but less expensive methods (such as diffusion theory) so that the spatial-spectrum coupling is represented accurately on a microscopic reaction rate level. It has a decisive advantage over Monte Carlo methods in computing the pin and assembly power profiles. In shielding problems where the penetration of the radiation can be deep, the method is used widely in design calculations. In oil-well logging problems which also involve deep penetration and have a stringent accuracy requirement on the detector responses, the method complements the Monte Carlo techniques. Recently, the discrete ordinates method with appropriate cross sections has been used in coupled photon-electron transport problems. In this paper the basic method is briefly reviewed, its applications illustrated, its merits and pitfalls discussed, and the recent advances in the attendant numerical techniques which have enhanced the capabilities of the method are enumerated. 28 refs., 1 fig.

During severe light water reactor accidents like Three-Mile Island (TMI-2), the reactor core can suffer considerable damage. Of interest here are melt progression, oxidation and gas phase natural convection in the reactor core after the fuel rods suffer a significant loss of geometry. This study describes a two-dimensional porous medium model that considers the motion of three fields: vapor, melt, and solid. A base case solution is described and the effects of oxidation, melt relocation, and Fe-Zr interactions are discussed. 16 refs., 7 figs.

Materials Control techniques are utilized to provide assurance that nuclear materials are being handled properly. In the event that materials are improperly handled or potentially malevolent activities utilizing nuclear materials are initiated, the materials control approach should provide a real-time indication to allow a rapid mitigating response. The appropriate response can range from correcting an inadvertent error to preventing an intentional insider-perpetrated incident. This paper is directed at the use of materials control techniques to deter and detect insider malevolence. 1 fig.

A two-part polyurethane foam has been tested in the laboratory and in the field to assess its utility in controlling lost circulation encountered when drilling geothermal wells. A field test was conducted in The Geysers in January, 1988, to evaluate the chemical formulation and downhole tool used to deploy the chemicals. Although the tool apparently functioned properly in the field test, the chemicals failed to expand sufficiently downhole, instead forming a dense polymer that may be ineffective in sealing loss zones. Subsequent laboratory tests conducted under simulated downhole conditions indicate that the foam chemical undergo sever mixing with water in the wellbore, which disturbs the kinetics of the chemical reaction more than was previously contemplated. The results indicate that without significant changes in the foam chemical formulation or delivery technique, the foam system will be ineffective in lost circulation control except under very favorable conditions. 4 refs., 6 figs., 2 tabs.

Results of fixed-bed hydropyrolysis and low temperature hydrogenation tests with a selection of coals and dispersed catalysts are described. Tar yields greater than 60% have been achieved in hydropyrolysis using sulphided molybdenum (Mo) with Mo concentrations as low as 0.1% daf coal for a number of bituminous coals. The hydrogenation tests indicated that the threshold temperature with these catalysts for oil generation from bituminous coals is 350{degree}C. 16 refs., 2 figs., 2 tabs.

We have developed a fast parallel version of an existing synthetic aperture radar (SAR) simulation program, SRIM. On a 1024-processor NCUBE hypercube it runs an order of magnitude faster than on a CRAY X-MP or CRAY Y-MP processor. This speed advantage is coupled with an order of magnitude advantage in machine acquisition cost. SRIM is a somewhat large (30,000 lines of Fortran 77) program designed for uniprocessors; its restructuring for hypercube provides new lessons in the task of altering older serial programs to run well on modern parallel architectures. We describe the techniques used for parallelization, and the performance obtained. Several novel parallel approaches to problems of task distribution, and direct output were required. These techniques increase performance and appear to have general applicability for massive parallelism. We describe the hierarchy necessary to dynamically manage (i.e., load balance) a large ensemble. The ensemble is used in a heterogeneous manner, with different programs on different parts of the hypercube. The heterogeneous approach takes advantage of the independent instruction streams possible on MIMD machines. 18 refs., 7 figs., 4 tabs.

The Buckshot code is a gridless particle simulation code which is used extensively at Sandia to study relativistic electron beam propagation in the ion-focused regime. The present version of the code evaluates the force on a particle by summing over all the other particles, thus the execution time is proportional to N{sup 2} where N is the number of simulation particles. A new gridless field solver has been developed with time scaling of N log N and the breakeven point between the old and new code is around N = 64 on the Cray X-MP computer. For N = 1000, the new solver is about nine times faster than the old version. The new solver is based on a solution of the two-dimensional Poisson equation which if Fourier decomposed in the azimuthal direction and the solution of the radial equation is represented by integrals over the charge density. These integrals are then replaced by sums over the simulation particles which are assumed to be point particles. The near-field singularity is removed by the Fourier decomposition so long as the number of Fourier modes is much less than the number of simulation particles. The algorithm is written in such a way that the field due to a given species is Fourier decomposed with respect to the center of mass of that species, thus it is possible to study linear and nonlinear ion hose physics with a very small number of azimuthal modes. Typically M = 2 is found to be sufficient for most IFR problems. The old and new solvers have been compared and the agreement is excellent. 2 refs., 3 figs.

It has been shown that a constant axial magnetic field does not affect the growth rate of the ion hose instability. However, if the field is allowed to vary in time, on the ion motion time scale, it is expected that particle orbits will be affected in a way that will result in a time varying beam wavelength. This can lead to detuning of the instability. Results of the rigid model with a time varying field of strength similar to the channel strength, show a significant decrease in the growth of the instability. Also, simulations using the BUCKSHOT code confirm the small effect of a steady magnetic field on hose growth and show a significant decrease in growth with a time varying field. 3 figs.

Sandia National Laboratories (SNL) has been involved in the evaluation of the sodium/sulfur technology for several years. Until recently, the effort concentrated on the performance of single cells. Recently, the evaluation of 4-cell string was initiated. The majority of the activity during the past two years has focused on cells from Chloride Silent Power, Limited (CSPL). To date, four groups of PB cells and 4-cell strings, which consisted of PB cells, have been evaluated. The first group of ten cells delivered to Sandia were on test for approximately one year. The majority of these cells failed due to corrosion problems in the sulfur seal. However, two cells completed over 800 cycles, and one of these cells completed nearly 1600 cycles. 4 figs., 1 tab.

A high detectivity infrared photodiode was constructed using an InAs{sub 0.15}Sb{sub 0.85}/InSb strained-layer superlattice (SLS). The surface passivated device exhibited detectivities {ge} 1 {times} 10{sup 10} cm{radical}Hz/W at wavelengths {le} 10 {mu}m. This device demonstrates the feasibility of a long wavelength, photovoltaic infrared detector technology based on InAsSb SLSs. 8 refs., 4 figs.