Publications

Baczewski, Andrew D.

Abstract not provided.

Baczewski, Andrew D.; Gamble, John K.; Jacobson, Noah T.; Muller, Richard P.; Nielsen, Erik N.

Abstract not provided.

Gamble, John K.; Baczewski, Andrew D.; Carroll, Malcolm; Harvey-Collard, Patrick H.; Jacobson, Noah T.; Maurer, Leon N.; Montano, Ines M.; Muller, Richard P.; Nielsen, Erik N.; Rudolph, Martin R.

Abstract not provided.

Jacobson, Noah T.; Baczewski, Andrew D.; Gamble, John K.; Muller, Richard P.; Nielsen, Erik N.; Rudolph, Martin R.; Harvey-Collard, Patrick H.; Carroll, Malcolm

Abstract not provided.

Shulenburger, Luke N.; Baczewski, Andrew D.; Zhu, Zhen Z.; Guan, Jie G.; Tomanek, David T.

Abstract not provided.

Magyar, Rudolph J.; Baczewski, Andrew D.

Abstract not provided.

Gamble, John K.; Baczewski, Andrew D.; Frees, Adam F.; Jacobson, Noah T.; Montano, Ines M.; Muller, Richard P.; Nielsen, Erik N.

Abstract not provided.

Baczewski, Andrew D.; Frees, Adam F.; Gamble, John K.; Gao, Xujiao G.; Jacobson, Noah T.; Mitchell, John A.; Montano, Ines M.; Muller, Richard P.; Nielsen, Erik N.

Abstract not provided.

Jacobson, Noah T.; Gamble, John K.; Baczewski, Andrew D.; Witzel, Wayne W.; Montano, Ines M.; Nielsen, Erik N.; Muller, Richard P.; Frees, Adam F.

Abstract not provided.

Shulenburger, Luke N.; Baczewski, Andrew D.; Zhu, Zhen Z.; Guan, Jie G.; Tomanek, David T.

Abstract not provided.

Muller, Richard P.; Aidun, John B.; Baczewski, Andrew D.; Gao, Xujiao G.; Metodi, Tzvetan S.; Mitchell, John A.; Sterk, Jonathan D.; Gamble, John K.; Blume-Kohout, Robin J.; Jacobson, Noah T.

Abstract not provided.

Baczewski, Andrew D.; Shulenburger, Luke N.; Desjarlais, Michael P.; Magyar, Rudolph J.

Abstract not provided.

Shulenburger, Luke N.; Baczewski, Andrew D.; Zhu, Zhen Z.; Guan, Jie G.; Tomanek, David T.

Abstract not provided.

Gamble, John K.; Jacobson, Noah T.; Nielsen, Erik N.; Baczewski, Andrew D.; Moussa, Jonathan E.; Montano, Ines M.; Muller, Richard P.

Abstract not provided.

arXiv posting

Gamble, John K.; Jacobson, Noah T.; Nielsen, Erik N.; Baczewski, Andrew D.; Moussa, Jonathan E.; Montano, Ines M.; Muller, Richard P.

Abstract not provided.

Baczewski, Andrew D.; Shulenburger, Luke N.; Desjarlais, Michael P.; Magyar, Rudolph J.

In recent years, DFT-MD has been shown to be a useful computational tool for exploring the properties of WDM. These calculations achieve excellent agreement with shock compression experiments, which probe the thermodynamic parameters of the Hugoniot state. New X-ray Thomson Scattering diagnostics promise to deliver independent measurements of electronic density and temperature, as well as structural information in shocked systems. However, they require the development of new levels of theory for computing the associated observables within a DFT framework. The experimentally observable x-ray scattering cross section is related to the electronic density-density response function, which is obtainable using TDDFT - a formally exact extension of conventional DFT that describes electron dynamics and excited states. In order to develop a capability for modeling XRTS data and, more generally, to establish a predictive capability for rst principles simulations of matter in extreme conditions, real-time TDDFT with Ehrenfest dynamics has been implemented in an existing PAW code for DFT-MD calculations. The purpose of this report is to record implementation details and benchmarks as the project advances from software development to delivering novel scienti c results. Results range from tests that establish the accuracy, e ciency, and scalability of our implementation, to calculations that are veri ed against accepted results in the literature. Aside from the primary XRTS goal, we identify other more general areas where this new capability will be useful, including stopping power calculations and electron-ion equilibration.

Physical Review Letters

Moussa, Jonathan E.; Baczewski, Andrew D.

Abstract not provided.

Journal of Physical Chemistry C

Baczewski, Andrew D.

Abstract not provided.

Baczewski, Andrew D.; Yarrington, Cole Y.; Bond, Stephen D.; Erikson, William W.; Lehoucq, Richard B.; Mondy, L.A.; Noble, David R.; Pierce, Flint P.; Roberts, Christine C.; Van Swol, Frank

The subject of this work is the development of models for the numerical simulation of matter, momentum, and energy balance in heterogeneous materials. These are materials that consist of multiple phases or species or that are structured on some (perhaps many) scale(s). By computational mechanics we mean to refer generally to the standard type of modeling that is done at the level of macroscopic balance laws (mass, momentum, energy). We will refer to the flow or flux of these quantities in a generalized sense as transport. At issue here are the forms of the governing equations in these complex materials which are potentially strongly inhomogeneous below some correlation length scale and are yet homogeneous on larger length scales. The question then becomes one of how to model this behavior and what are the proper multi-scale equations to capture the transport mechanisms across scales. To address this we look to the area of generalized stochastic process that underlie the transport processes in homogeneous materials. The archetypal example being the relationship between a random walk or Brownian motion stochastic processes and the associated Fokker-Planck or diffusion equation. Here we are interested in how this classical setting changes when inhomogeneities or correlations in structure are introduced into the problem. Aspects of non-classical behavior need to be addressed, such as non-Fickian behavior of the mean-squared-displacement (MSD) and non-Gaussian behavior of the underlying probability distribution of jumps. We present an experimental technique and apparatus built to investigate some of these issues. We also discuss diffusive processes in inhomogeneous systems, and the role of the chemical potential in diffusion of hard spheres is considered. Also, the relevance to liquid metal solutions is considered. Finally we present an example of how inhomogeneities in material microstructure introduce fluctuations at the meso-scale for a thermal conduction problem. These fluctuations due to random microstructures also provide a means of characterizing the aleatory uncertainty in material properties at the mesoscale.

Bond, Stephen D.; Baczewski, Andrew D.

Abstract not provided.

Shulenburger, Luke N.; Baczewski, Andrew D.

Abstract not provided.

Magyar, Rudolph J.; Shulenburger, Luke N.; Baczewski, Andrew D.

Abstract not provided.

Journal of Chemical Physics

Baczewski, Andrew D.; Bond, Stephen D.

Generalized Langevin dynamics (GLD) arise in the modeling of a number of systems, ranging from structured fluids that exhibit a viscoelastic mechanical response, to biological systems, and other media that exhibit anomalous diffusive phenomena. Molecular dynamics (MD) simulations that include GLD in conjunction with external and/or pairwise forces require the development of numerical integrators that are efficient, stable, and have known convergence properties. In this article, we derive a family of extended variable integrators for the Generalized Langevin equation with a positive Prony series memory kernel. Using stability and error analysis, we identify a superlative choice of parameters and implement the corresponding numerical algorithm in the LAMMPS MD software package. Salient features of the algorithm include exact conservation of the first and second moments of the equilibrium velocity distribution in some important cases, stable behavior in the limit of conventional Langevin dynamics, and the use of a convolution-free formalism that obviates the need for explicit storage of the time history of particle velocities. Capability is demonstrated with respect to accuracy in numerous canonical examples, stability in certain limits, and an exemplary application in which the effect of a harmonic confining potential is mapped onto a memory kernel.

Proposed for publication in Engineering with Computers.

Baczewski, Andrew D.

Abstract not provided.

IEEE Transactions on Antennas and Propagation

Baczewski, Andrew D.; Dault, Daniel D.; Shanker, Balasubramaniam S.

We present an algorithm for the fast and efficient solution of integral equations that arise in the analysis of scattering from periodic arrays of PEC objects, such as multiband frequency selective surfaces (FSS) or metamaterial structures. Our approach relies upon the method of Accelerated Cartesian Expansions (ACE) to rapidly evaluate the requisite potential integrals. ACE is analogous to FMM in that it can be used to accelerate the matrix vector product used in the solution of systems discretized using MoM. Here, ACE provides linear scaling in both CPU time and memory. Details regarding the implementation of this method within the context of periodic systems are provided, as well as results that establish error convergence and scalability. In addition, we also demonstrate the applicability of this algorithm by studying several exemplary electrically dense systems.