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5 results on '"Corbett Battaile"'

1. A Multi-Phase Modeling Framework Suitable for Dynamic Applications

Author

Nathan R. Barton, Darby J. Luscher, Corbett Battaile, Justin L. Brown, Miles Buechler, Leonid Burakovsky, Scott Crockett, Carl Greeff, Ann E. Mattsson, Michael B. Prime, and William J. Schill

Subjects
multi-phase, dynamic loading, strength, equation of state, phase kinetics, Mining engineering. Metallurgy, TN1-997
Abstract

Under dynamic loading conditions and the associated extreme conditions many metals will undergo phase transformations. The change in crystal structure associated with solid–solid phase transformations can significantly alter the subsequent mechanical response of the material. For the interpretation of experiments involving dynamic loading it is beneficial to have a modeling framework that captures key features of the material response while remaining relatively simple. We introduce a candidate framework and apply it to the metal tin to highlight a range of behaviors that are captured by the model. We also discuss potential extensions to capture additional behaviors that could be important for certain materials and loading scenarios. The model is useful for analysis of results from dynamic experiments and offers a point of departure for more complex model formulations.

Published
2022
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3. Parallel simulation via SPPARKS of on-lattice kinetic and Metropolis Monte Carlo models for materials processing

Author

John A Mitchell, Fadi Abdeljawad, Corbett Battaile, Cristina Garcia-Cardona, Elizabeth A Holm, Eric R Homer, Jon Madison, Theron M Rodgers, Aidan P Thompson, Veena Tikare, Ed Webb, and Steven J Plimpton

Subjects
Mechanics of Materials, Modeling and Simulation, General Materials Science, Condensed Matter Physics, Computer Science Applications
Abstract

SPPARKS is an open-source parallel simulation code for developing and running various kinds of on-lattice Monte Carlo models at the atomic or meso scales. It can be used to study the properties of solid-state materials as well as model their dynamic evolution during processing. The modular nature of the code allows new models and diagnostic computations to be added without modification to its core functionality, including its parallel algorithms. A variety of models for microstructural evolution (grain growth), solid-state diffusion, thin film deposition, and additive manufacturing (AM) processes are included in the code. SPPARKS can also be used to implement grid-based algorithms such as phase field or cellular automata models, to run either in tandem with a Monte Carlo method or independently. For very large systems such as AM applications, the Stitch I/O library is included, which enables only a small portion of a huge system to be resident in memory. In this paper we describe SPPARKS and its parallel algorithms and performance, explain how new Monte Carlo models can be added, and highlight a variety of applications which have been developed within the code.

Published
2023
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5. Modeling of friction-induced deformation and microstructures

Author

Joseph Michael, Somuri Prasad, John Jungk, Megan Cordill, Douglas Bammann, Corbett Battaile, Neville Moody, and Bhaskar Majumdar

Subjects
Contact mechanics, Materials science, Recrystallization (geology), Metallurgy, Surface roughness, Lubrication, Dislocation, Deformation (engineering), Composite material, Grain Boundary Sliding, Electron backscatter diffraction
Abstract

Frictional contact results in surface and subsurface damage that could influence the performance, aging, and reliability of moving mechanical assemblies. Changes in surface roughness, hardness, grain size and texture often occur during the initial run-in period, resulting in the evolution of subsurface layers with characteristic microstructural features that are different from those of the bulk. The objective of this LDRD funded research was to model friction-induced microstructures. In order to accomplish this objective, novel experimental techniques were developed to make friction measurements on single crystal surfaces along specific crystallographic surfaces. Focused ion beam techniques were used to prepare cross-sections of wear scars, and electron backscattered diffraction (EBSD) and TEM to understand the deformation, orientation changes, and recrystallization that are associated with sliding wear. The extent of subsurface deformation and the coefficient of friction were strongly dependent on the crystal orientation. These experimental observations and insights were used to develop and validate phenomenological models. A phenomenological model was developed to elucidate the relationships between deformation, microstructure formation, and friction during wear. The contact mechanics problem was described by well-known mathematical solutions for the stresses during sliding friction. Crystal plasticity theory was used to describe the evolution of dislocation content in the worn material, which in turn provided an estimate of the characteristic microstructural feature size as a function of the imposed strain. An analysis of grain boundary sliding in ultra-fine-grained material provided a mechanism for lubrication, and model predictions of the contribution of grain boundary sliding (relative to plastic deformation) to lubrication were in good qualitative agreement with experimental evidence. A nanomechanics-based approach has been developed for characterizing the mechanical response of wear surfaces. Coatings are often required to mitigate friction and wear. Amongst other factors, plastic deformation of the substrate determines the coating-substrate interface reliability. Finite element modeling has been applied to predict the plastic deformation for the specific case of diamond-like carbon (DLC) coated Ni alloy substrates.

Published
2006
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