Your search keyword '"Don Berry"' showing total 6 results

1. 'Parking-garage' structures in nuclear astrophysics and cellular biophysics

Author

Greg Huber, A. S. Schneider, Don Berry, Matthew Caplan, and Charles Horowitz

Subjects

Physics, 010308 nuclear & particles physics, media_common.quotation_subject, Frustration, Nuclear matter, 01 natural sciences, Nuclear pasta, Nuclear physics, Neutron star, Molecular dynamics, Chemical physics, 0103 physical sciences, Coulomb, Nuclear astrophysics, Neutron, 010306 general physics, media_common

Abstract

A striking shape was recently observed for the endoplasmic reticulum, a cellular organelle consisting of stacked sheets connected by helical ramps [Terasaki et al., Cell 154, 285 (2013)]. This shape is interesting both for its biological function, to synthesize proteins using an increased surface area for ribosome factories, and its geometric properties that may be insensitive to details of the microscopic interactions. In the present work, we find very similar shapes in our molecular dynamics simulations of the nuclear pasta phases of dense nuclear matter that are expected deep in the crust of neutron stars. There are dramatic differences between nuclear pasta and terrestrial cell biology. Nuclear pasta is 14 orders of magnitude denser than the aqueous environs of the cell nucleus and involves strong interactions between protons and neutrons, while cellular-scale biology is dominated by the entropy of water and complex assemblies of biomolecules. Nonetheless, the very similar geometry suggests both systems may have similar coarse-grained dynamics and that the shapes are indeed determined by geometrical considerations, independent of microscopic details. Many of our simulations self-assemble into flat sheets connected by helical ramps. These ramps may impact the thermal and electrical conductivities, viscosity, shear modulus, and breaking strain of neutron star crust. The interaction we use, with Coulomb frustration, may provide a simple model system that reproduces many biologically important shapes.

Published

2016

2. Pasta nucleosynthesis: Molecular dynamics simulations of nuclear statistical equilibrium

Author

Charles Horowitz, Matthew Caplan, A. S. Schneider, and Don Berry

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Physics, Nuclear and High Energy Physics, Range (particle radiation), Nuclear Theory, Proton, FOS: Physical sciences, Nuclear matter, Nuclear pasta, Nuclear Theory (nucl-th), Nuclear physics, Neutron star, Nucleosynthesis, r-process, Atomic physics, Astrophysics - High Energy Astrophysical Phenomena, Nuclear Experiment, Nucleon

Abstract

Background: Exotic non-spherical nuclear pasta shapes are expected in nuclear matter at just below saturation density because of competition between short range nuclear attraction and long range Coulomb repulsion. Purpose: We explore the impact of nuclear pasta on nucleosynthesis, during neutron star mergers, as cold dense nuclear matter is ejected and decompressed. Methods: We perform classical molecular dynamics simulations with 51200 and 409600 nucleons, that are run on GPUs. We expand our simulation region to decompress systems from an initial density of 0.080 fm^{-3} down to 0.00125 fm^{-3}. We study proton fractions of Y_P=0.05, 0.10, 0.20, 0.30, and 0.40 at T =0.5, 0.75, and 1.0 MeV. We calculate the composition of the resulting systems using a cluster algorithm. Results: We find final compositions that are in good agreement with nuclear statistical equilibrium models for temperatures of 0.75 and 1 MeV. However, for proton fractions greater than Y_P=0.2 at a temperature of T = 0.5 MeV, the MD simulations produce non-equilibrium results with large rod-like nuclei. Conclusions: Our MD model is valid at higher densities than simple nuclear statistical equilibrium models and may help determine the initial temperatures and proton fractions of matter ejected in mergers., 13 pages

Published

2015

3. Direct molecular dynamics simulation of liquid-solid phase equilibria for a three-component plasma

Author

Charles Horowitz, J. Hughto, A. S. Schneider, Don Berry, Zach Medin, and Andrew Cumming

Subjects

Physics, chemistry.chemical_element, White dwarf, Thermodynamics, Plasma, 01 natural sciences, Neon, Molecular dynamics, Molecular geometry, chemistry, 13. Climate action, Impurity, Phase (matter), 0103 physical sciences, 010306 general physics, 010303 astronomy & astrophysics, Energy (signal processing)

Abstract

The neutron-rich isotope ${}^{22}$Ne may be a significant impurity in carbon and oxygen white dwarfs and could impact how the stars freeze. We perform molecular dynamics simulations to determine the influence of ${}^{22}$Ne in carbon-oxygen-neon systems on liquid-solid phase equilibria. Both liquid and solid phases are present simultaneously in our simulation volumes. We identify liquid, solid, and interface regions in our simulations using a bond angle metric. In general we find good agreement for the composition of liquid and solid phases between our MD simulations and the semianalytic model of Medin and Cumming. The trace presence of a third component, neon, does not appear to strongly impact the chemical separation found previously for two-component carbon and oxygen systems. This suggests that small amounts of ${}^{22}$Ne may not qualitatively change how the material in white dwarf stars freezes. However, we do find systematically lower melting temperatures (higher $\ensuremath{\Gamma}$) in our MD simulations compared to the semianalytic model. This difference seems to grow with impurity parameter ${Q}_{\text{imp}}$ and suggests a problem with simple corrections to the linear mixing rule for the free energy of multicomponent solid mixtures that is used in the semianalytic model.

Published

2012

4. Structure of accreted neutron star crust

Author

Don Berry and Charles Horowitz

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Physics, Nuclear reaction, Nuclear and High Energy Physics, Nuclear Theory, Condensed matter physics, Proton, Scattering, FOS: Physical sciences, Electron, Nuclear Theory (nucl-th), Shear modulus, Neutron star, Astrophysics - Solar and Stellar Astrophysics, Impurity, Nucleosynthesis, Condensed Matter::Superconductivity, Condensed Matter::Strongly Correlated Electrons, Atomic physics, Astrophysics - High Energy Astrophysical Phenomena, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

Using molecular dynamics simulations, we determine the structure of neutron star crust made of rapid proton capture nucleosynthesis material. We find a regular body centered cubic lattice, even with the large number of impurities that are present. Low charge $Z$ impurities tend to occupy interstitial positions, while high $Z$ impurities tend to occupy substitutional lattice sites. We find strong attractive correlations between low $Z$ impurities that could significantly increase the rate of pycnonuclear (density driven) nuclear reactions. The thermal conductivity is significantly reduced by electron impurity scattering. Our results will be used in future work to study the effects of impurities on mechanical properties such as the shear modulus and breaking strain., 7 pages, 9 figures, added A values to table I, version as published

Published

2009

5. Fusion of neutron-rich oxygen isotopes in the crust of accreting neutron stars

Author

Don Berry, H. Dussan, and Charles Horowitz

Subjects

Physics, Nuclear and High Energy Physics, Thermonuclear fusion, Nuclear Theory, Electron capture, Astrophysics::High Energy Astrophysical Phenomena, Astrophysics (astro-ph), FOS: Physical sciences, Astrophysics, Effective nuclear charge, Isotopes of oxygen, Nuclear Theory (nucl-th), Nuclear physics, Neutron star, Nuclear fusion, Neutron, Atomic number, Nuclear Experiment

Abstract

Fusion reactions in the crust of an accreting neutron star are an important source of heat, and the depth at which these reactions occur is important for determining the temperature profile of the star. Fusion reactions depend strongly on the nuclear charge $Z$. Nuclei with $Z\le 6$ can fuse at low densities in a liquid ocean. However, nuclei with Z=8 or 10 may not burn until higher densities where the crust is solid and electron capture has made the nuclei neutron rich. We calculate the $S$ factor for fusion reactions of neutron rich nuclei including $^{24}$O + $^{24}$O and $^{28}$Ne + $^{28}$Ne. We use a simple barrier penetration model. The $S$ factor could be further enhanced by dynamical effects involving the neutron rich skin. This possible enhancement in $S$ should be studied in the laboratory with neutron rich radioactive beams. We model the structure of the crust with molecular dynamics simulations. We find that the crust of accreting neutron stars may contain micro-crystals or regions of phase separation. Nevertheless, the screening factors that we determine for the enhancement of the rate of thermonuclear reactions are insensitive to these features. Finally, we calculate the rate of thermonuclear $^{24}$O + $^{24}$O fusion and find that $^{24}$O should burn at densities near $10^{11}$ g/cm$^3$. The energy released from this and similar reactions may be important for the temperature profile of the star., Comment: 7 pages, 4 figs, minor changes, to be published in Phys. Rev. C

Published

2008

6. Dynamical response of the nuclear 'pasta' in neutron star crusts

Author

Don Berry, M. A. Pérez-García, Charles Horowitz, and Jorge Piekarewicz

Subjects

Physics, Nuclear and High Energy Physics, Nuclear Theory, media_common.quotation_subject, Astrophysics (astro-ph), FOS: Physical sciences, Frustration, Astrophysics, Nuclear matter, Nuclear pasta, Density wave theory, Nuclear Theory (nucl-th), Nuclear physics, Neutron star, State of matter, Neutrino, Atomic physics, Nuclear Experiment, Nucleon, media_common

Abstract

The nuclear pasta -- a novel state of matter having nucleons arranged in a variety of complex shapes -- is expected to be found in the crust of neutron stars and in core-collapse supernovae at subnuclear densities of about $10^{14}$ g/cm$^3$. Due to frustration, a phenomenon that emerges from the competition between short-range nuclear attraction and long-range Coulomb repulsion, the nuclear pasta displays a preponderance of unique low-energy excitations. These excitations could have a strong impact on many transport properties, such as neutrino propagation through stellar environments. The excitation spectrum of the nuclear pasta is computed via a molecular-dynamics simulation involving up to 100,000 nucleons. The dynamic response of the pasta displays a classical plasma oscillation in the 1-2 MeV region. In addition, substantial strength is found at low energies. Yet this low-energy strength is missing from a simple ion model containing a single-representative heavy nucleus. The low-energy strength observed in the dynamic response of the pasta is likely to be a density wave involving the internal degrees of freedom of the clusters., Comment: 4 pages, 3 figures, Phys Rev C in press

Published

2005