Publications

Ingraham, Mathew D.; Bolintineanu, Dan S.; Rao, Rekha R.; Bauer, Stephen J.; Quintana, Enrico C.; Lechman, Jeremy B.

Abstract not provided.

Journal of the Electrochemical Society

Reinholz, Emilee L.; Roberts, Scott A.; Apblett, Christopher A.; Lechman, Jeremy B.; Schunk, Randy

Electrical conductivity is key to the performance of thermal battery cathodes. In this work we present the effects of manufacturing and processing conditions on the electrical conductivity of Li/FeS2 thermal battery cathodes. We use finite element simulations to compute the conductivity of three-dimensional microcomputed tomography cathode microstructures and compare results to experimental impedance spectroscopy measurements. A regression analysis reveals a predictive relationship between composition, processing conditions, and electrical conductivity; a trend which is largely erased after thermally-induced deformation. The trend applies to both experimental and simulation results, although is not as apparent in simulations. This research is a step toward a more fundamental understanding of the effects of processing and composition on thermal battery component microstructure, properties, and performance.

Ingraham, Mathew D.; Bolintineanu, Dan S.; Rao, Rekha R.; Quintana, Enrico C.; Bauer, Stephen J.; Lechman, Jeremy B.

Abstract not provided.

Rao, Rekha R.; Ingraham, Mathew D.; Bolintineanu, Dan S.; Grillet, Anne M.; Lechman, Jeremy B.; Quintana, Enrico C.; Mondy, L.A.; Roberts, Christine C.; Bauer, Stephen J.

Abstract not provided.

Rao, Rekha R.; Mondy, L.A.; Ingraham, Mathew D.; Subia, Samuel R.; Hopkins, Matthew M.; Bolintineanu, Dan S.; Lechman, Jeremy B.; Altobelli, Steve A.

Abstract not provided.

Boechler, Nicholas B.; Brake, Matthew R.; McGonigle, Lorcan M.; Kuhr, Bryan R.; Wallen, Samuel P.; Lechman, Jeremy B.; Bolintineanu, Dan S.

Two of the central challenges in the mechanical design of components in nuclear systems are the dissipation of energy from external shocks and the localization of energy in energetic materials. This research seeks to address these problems by developing a patterned granular microstructure that can be optimized to direct or impede the transfer of energy carried by stress waves. Such structures require the development of a manufacturing technique that can yield perfectly ordered lattices. Two branches of research are detailed here: the development of a sphere-by-sphere additive manufacturing technique, and the development of a framework for modeling the technique in order to guide future improvements. Proof of concept of the method is demonstrated, and recommendations for future work are made.

Bolintineanu, Dan S.; Lechman, Jeremy B.

Abstract not provided.

Ingraham, Mathew D.; Bolintineanu, Dan S.; Rao, Rekha R.; Bauer, Stephen J.; Quintana, Enrico C.; Lechman, Jeremy B.

Abstract not provided.

Ingraham, Mathew D.; Bauer, Stephen J.; Quintana, Enrico C.; Bolintineanu, Dan S.; Rao, Rekha R.; Lechman, Jeremy B.

Abstract not provided.

Ingraham, Mathew D.; Bauer, Stephen J.; Quintana, Enrico C.; Bolintineanu, Dan S.; Rao, Rekha R.; Lechman, Jeremy B.

Abstract not provided.

Bolintineanu, Dan S.; Lechman, Jeremy B.

Abstract not provided.

Kuhr, Bryan K.; Brake, Matthew R.; Lechman, Jeremy B.

The following details the implementation of an analytical elastic plastic contact model with strain hardening for normal im pacts into the LAMMPS granular package. The model assumes that, upon impact, the co llision has a period of elastic loading followed by a period of mixed elastic plas tic loading, with contributions to each mechanism estimated by a hyperbolic seca nt weight function. This function is implemented in the LAMMPS source code as the pair style gran/ep/history. Preliminary tests, simulating the pouring of pure nickel spheres, showed the elastic/plastic model took 1.66x as long as similar runs using gran/hertz/history.

Bolintineanu, Dan S.; Lechman, Jeremy B.; Grest, Gary S.; Silbert, Leonardo E.

Abstract not provided.

Ingraham, Mathew D.; Bauer, Stephen J.; Quintana, Enrico C.; Bolintineanu, Dan S.; Rao, Rekha R.; Lechman, Jeremy B.

Abstract not provided.

Lechman, Jeremy B.; Battaile, Corbett C.; Bolintineanu, Dan S.; Cooper, Marcia A.; Erikson, William W.; Foiles, Stephen M.; Kay, Jeffrey J.; Phinney, Leslie M.; Piekos, Edward S.; Specht, Paul E.; Wixom, Ryan R.; Yarrington, Cole Y.

This report summarizes a project in which the authors sought to develop and deploy: (i) experimental techniques to elucidate the complex, multiscale nature of thermal transport in particle-based materials; and (ii) modeling approaches to address current challenges in predicting performance variability of materials (e.g., identifying and characterizing physical- chemical processes and their couplings across multiple length and time scales, modeling information transfer between scales, and statically and dynamically resolving material structure and its evolution during manufacturing and device performance). Experimentally, several capabilities were successfully advanced. As discussed in Chapter 2 a flash diffusivity capability for measuring homogeneous thermal conductivity of pyrotechnic powders (and beyond) was advanced; leading to enhanced characterization of pyrotechnic materials and properties impacting component development. Chapter 4 describes success for the first time, although preliminary, in resolving thermal fields at speeds and spatial scales relevant to energetic components. Chapter 7 summarizes the first ever (as far as the authors know) application of TDTR to actual pyrotechnic materials. This is the first attempt to actually characterize these materials at the interfacial scale. On the modeling side, new capabilities in image processing of experimental microstructures and direct numerical simulation on complicated structures were advanced (see Chapters 3 and 5). In addition, modeling work described in Chapter 8 led to improved prediction of interface thermal conductance from first principles calculations. Toward the second point, for a model system of packed particles, significant headway was made in implementing numerical algorithms and collecting data to justify the approach in terms of highlighting the phenomena at play and pointing the way forward in developing and informing the kind of modeling approach originally envisioned (see Chapter 6). In both cases much more remains to be accomplished.

Ingraham, Mathew D.; Bauer, Stephen J.; Bolintineanu, Dan S.; Rao, Rekha R.; Lechman, Jeremy B.; Quintana, Enrico C.

Abstract not provided.

Phinney, Leslie M.; Erikson, William W.; Lechman, Jeremy B.

Abstract not provided.

Computational Particle Mechanics

Bolintineanu, Dan S.; Grest, Gary S.; Lechman, Jeremy B.; Pierce, Flint P.; Plimpton, Steven J.; Schunk, Randy

We present a review and critique of several methods for the simulation of the dynamics of colloidal suspensions at the mesoscale. We focus particularly on simulation techniques for hydrodynamic interactions, including implicit solvents (Fast Lubrication Dynamics, an approximation to Stokesian Dynamics) and explicit/particle-based solvents (Multi-Particle Collision Dynamics and Dissipative Particle Dynamics). Several variants of each method are compared quantitatively for the canonical system of monodisperse hard spheres, with a particular focus on diffusion characteristics, as well as shear rheology and microstructure. In all cases, we attempt to match the relevant properties of a well-characterized solvent, which turns out to be challenging for the explicit solvent models. Reasonable quantitative agreement is observed among all methods, but overall the Fast Lubrication Dynamics technique shows the best accuracy and performance. We also devote significant discussion to the extension of these methods to more complex situations of interest in industrial applications, including models for non-Newtonian solvent rheology, non-spherical particles, drying and curing of solvent and flows in complex geometries. This work identifies research challenges and motivates future efforts to develop techniques for quantitative, predictive simulations of industrially relevant colloidal suspension processes.

Phinney, Leslie M.; Erikson, William W.; Lechman, Jeremy B.

Abstract not provided.

Lechman, Jeremy B.

Abstract not provided.

Lechman, Jeremy B.

Abstract not provided.

Lechman, Jeremy B.

Abstract not provided.

Plimpton, Steven J.; Lane, James M.; Lechman, Jeremy B.

Abstract not provided.

Lechman, Jeremy B.

Abstract not provided.

Lechman, Jeremy B.; Givler, R.C.

Active brazes have been used for many years to produce bonds between metal and ceramic objects. By including a relatively small of a reactive additive to the braze one seeks to improve the wetting and spreading behavior of the braze. The additive modifies the substrate, either by a chemical surface reaction or possibly by alloying. By its nature, the joining process with active brazes is a complex nonequilibrium non-steady state process that couples chemical reaction, reactant and product diffusion to the rheology and wetting behavior of the braze. Most of the these subprocesses are taking place in the interfacial region, most are difficult to access by experiment. To improve the control over the brazing process, one requires a better understanding of the melting of the active braze, rate of the chemical reaction, reactant and product diffusion rates, nonequilibrium composition-dependent surface tension as well as the viscosity. This report identifies ways in which modeling and theory can assist in improving our understanding.