Your search keyword '"Falato, Michael J."' showing total 4 results

1. Halted-Pendulum Relaxation: Application to White Dwarf Binary Initial Data

Author

Kaltenborn, M. Alexander R., Falato, Michael J., Korobkin, Oleg, Sagert, Irina, Even, Wesley P., Kaltenborn, M. Alexander R., Falato, Michael J., Korobkin, Oleg, Sagert, Irina, and Even, Wesley P.

Abstract

Studying compact star binaries and their mergers is integral to determining progenitors for observable transients. Today, compact-star mergers are typically studied via state-of-the-art computational fluid dynamics codes. One such numerical technique, Smoothed Particle Hydrodynamics (SPH), is frequently chosen for its excellent mass, energy, and momentum conservation. The natural treatment of vacuum and the ability to represent highly irregular morphologies make SPH an excellent tool for the study of compact-star binaries and mergers. For many scenarios, including binary systems, the outcome of simulations is only as accurate as the initial conditions. For SPH, it is essential to ensure that the particles are distributed regularly, representing the initial density profile but without long-range correlations. Particle noise in the form of high-frequency local motion and low-frequency global dynamics must be damped out. Damping the latter can be as computationally intensive as the actual simulation. We discuss a new and straightforward relaxation method, Halted-Pendulum Relaxation (HPR), to remove global oscillation modes of SPH particle configurations. In combination with effective external potentials representing gravitational and orbital forces, we show that HPR has an excellent performance in efficiently relaxing SPH particles to the desired density distribution and removing global oscillation modes. We compare the method to frequently used relaxation approaches and test it on a white dwarf binary model at its Roche lobe overflow limit. We highlight the importance of our method in achieving accurate initial conditions and its effect on achieving circular orbits and realistic accretion rates when compared with other general relaxation methods.

Published

2022

2. Modeling Solids in Nuclear Astrophysics with Smoothed Particle Hydrodynamics

Author

Sagert, Irina, Korobkin, Oleg, Tews, Ingo, Tsao, Bing-Jyun, Lim, Hyun, Falato, Michael J., Loiseau, Julien, Sagert, Irina, Korobkin, Oleg, Tews, Ingo, Tsao, Bing-Jyun, Lim, Hyun, Falato, Michael J., and Loiseau, Julien

Abstract

Smoothed Particle Hydrodynamics (SPH) is a frequently applied tool in computational astrophysics to solve the fluid dynamics equations governing the systems under study. For some problems, for example when involving asteroids and asteroid impacts, the additional inclusion of material strength is necessary in order to accurately describe the dynamics. In compact stars, that is white dwarfs and neutron stars, solid components are also present. Neutron stars have a solid crust which is the strongest material known in nature. However, their dynamical evolution, when modeled via SPH or other computational fluid dynamics codes, is usually described as a purely fluid dynamics problem. Here, we present the first 3D simulations of neutron-star crustal toroidal oscillations including material strength with the Los Alamos National Laboratory SPH code FleCSPH. In the first half of the paper, we present the numerical implementation of solid material modeling together with standard tests. The second half is on the simulation of crustal oscillations in the fundamental toroidal mode. Here, we dedicate a large fraction of the paper to approaches which can suppress numerical noise in the solid. If not minimized, the latter can dominate the crustal motion in the simulations., Comment: 28 pages, 34 figures

Published

2022

3. Plasma Image Classification Using Cosine Similarity Constrained CNN

Author

Falato, Michael J., Wolfe, Bradley T., Natan, Tali M., Zhang, Xinhua, Marshall, Ryan S., Zhou, Yi, Bellan, Paul M., Wang, Zhehui, Falato, Michael J., Wolfe, Bradley T., Natan, Tali M., Zhang, Xinhua, Marshall, Ryan S., Zhou, Yi, Bellan, Paul M., and Wang, Zhehui

Abstract

Plasma jets are widely investigated both in the laboratory and in nature. Astrophysical objects such as black holes, active galactic nuclei, and young stellar objects commonly emit plasma jets in various forms. With the availability of data from plasma jet experiments resembling astrophysical plasma jets, classification of such data would potentially aid in investigating not only the underlying physics of the experiments but the study of astrophysical jets. In this work we use deep learning to process all of the laboratory plasma images from the Caltech Spheromak Experiment spanning two decades. We found that cosine similarity can aid in feature selection, classify images through comparison of feature vector direction, and be used as a loss function for the training of AlexNet for plasma image classification. We also develop a simple vector direction comparison algorithm for binary and multi-class classification. Using our algorithm we demonstrate 93% accurate binary classification to distinguish unstable columns from stable columns and 92% accurate five-way classification of a small, labeled data set which includes three classes corresponding to varying levels of kink instability., Comment: 16 pages, 12 figures, For submission to Journal of Plasma Physics

Published

2022

4. Machine Learning for Detection of 3D Features using sparse X-ray data

Author

Wolfe, Bradley T., Falato, Michael J., Zhang, Xinhua, Nguyen-Fotiadis, Nga T. T., Sauppe, J. P., Kozlowski, P. M., Keiter, P. A., Reinovsky, R. E., Batha, S. A., Wang, Zhehui, Wolfe, Bradley T., Falato, Michael J., Zhang, Xinhua, Nguyen-Fotiadis, Nga T. T., Sauppe, J. P., Kozlowski, P. M., Keiter, P. A., Reinovsky, R. E., Batha, S. A., and Wang, Zhehui

Abstract

In many inertial confinement fusion experiments, the neutron yield and other parameters cannot be completely accounted for with one and two dimensional models. This discrepancy suggests that there are three dimensional effects which may be significant. Sources of these effects include defects in the shells and shell interfaces, the fill tube of the capsule, and the joint feature in double shell targets. Due to their ability to penetrate materials, X-rays are used to capture the internal structure of objects. Methods such as Computational Tomography use X-ray radiographs from hundreds of projections in order to reconstruct a three dimensional model of the object. In experimental environments, such as the National Ignition Facility and Omega-60, the availability of these views is scarce and in many cases only consist of a single line of sight. Mathematical reconstruction of a 3D object from sparse views is an ill-posed inverse problem. These types of problems are typically solved by utilizing prior information. Neural networks have been used for the task of 3D reconstruction as they are capable of encoding and leveraging this prior information. We utilize half a dozen different convolutional neural networks to produce different 3D representations of ICF implosions from the experimental data. We utilize deep supervision to train a neural network to produce high resolution reconstructions. We use these representations to track 3D features of the capsules such as the ablator, inner shell, and the joint between shell hemispheres. Machine learning, supplemented by different priors, is a promising method for 3D reconstructions in ICF and X-ray radiography in general.

Published

2022