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272 results on '"Daniel Neuhauser"'

251. Near-field for electrodynamics at sub-wavelength scales: Generalizing to an arbitrary number of dielectrics

Author

Yi Gao, Daniel Neuhauser, and Shaohong L. Li

Subjects
Physics, Silver, Vacuum, Condensed matter physics, Surface plasmon, Electric Conductivity, Metal Nanoparticles, Physics::Optics, General Physics and Astronomy, Near and far field, Dielectric, Surface Plasmon Resonance, Silicon Dioxide, Lipids, Nanostructures, Dipole, Electrical resistivity and conductivity, Conjugate gradient method, Quantum mechanics, Quasiparticle, Nanotechnology, Gold, Physical and Theoretical Chemistry, Poisson's equation, Algorithms
Abstract

We extend the recently developed near-field (NF) method to include an arbitrary number of dielectrics. NF assumes that the dipoles and fields respond instantaneously to the density, without retardation. The central task in NF is the solution of the Poisson equation for every time step, which is here done by a conjugate gradient method which handles any dielectric distribution. The optical response of any metal-dielectric system can now be studied very efficiently in the near field region. The improved NF method is first applied to simple benchmark systems: a gold nanoparticle in vacuum and embedded in silica. The surface plasmons in these systems and their dependence on the dielectrics are reproduced in the new NF approach. As a further application, we study a silver nanoparticle-based structure for the optical detection of a "lipid" (i.e., dielectric) layer in water, where the layer is wrapping around part of the metallic nanostructure. We show the ~0.1-0.15 eV shift in the spectrum due to the presence of the layer, for both spherical and non-spherical (sphere+rod) systems with various polarizations.

Published
2012

252. A time-dependent semiempirical approach to determining excited states

Author

Michael R. Wall, Lizette A. Bartell, and Daniel Neuhauser

Subjects
Basis (linear algebra), Chemistry, Excited state, General Physics and Astronomy, Almost surely, Physical and Theoretical Chemistry, Perturbation theory, Atomic physics, Excitation, Basis set, Spectral line, Fock space
Abstract

We study a time-dependent semiempirical method to determine excitation energies, TD-PM3. This semiempirical method allows large molecules to be treated. A Linear-response Chebyshev approach yields the TD-PM3 spectrum very efficiently. Spectra and excitation energies were tested by comparing it with the results obtained using TD-DFT (Time Dependent-Density Functional Theory), using both small and large basis sets. They were also compared to PM3-CI, Time Dependent-Hartree Fock using the STO-3G basis set, and to experiment. TD-PM3 results generally match better the large-basis set calculations than the small-basis TD-DFT do; excitation energies are almost always accurate to within about 20% or less, except for a few small molecules. Accuracy improves as the molecules get larger.

Published
2010

253. Nonlinear nanopolaritonics: Finite-difference time-domain Maxwell–Schrödinger simulation of molecule-assisted plasmon transfer

Author

Kenneth Lopata and Daniel Neuhauser

Subjects
Condensed matter physics, Field (physics), Chemistry, Physics::Optics, General Physics and Astronomy, Resonance (particle physics), Molecular physics, Dipole, Excited state, Polariton, Physical and Theoretical Chemistry, Plasmon, Excitation, Localized surface plasmon
Abstract

The effect of nonlinear excitations of a nearby two-state dipolar molecule on plasmon transfer across a pair of spherical gold nanoparticles is studied numerically using a split field finite-difference time-domain Maxwell-Schrödinger approach [K. Lopata and D. Neuhauser, J. Chem. Phys. 130, 104707 (2009)]. It is observed in the linear response regime that the molecule has a drastic effect on plasmon transfer; specifically, there is a Fano-type resonance that serves to scatter localized plasmons from x-polarization to y-polarization. With increasing nonlinearity of the molecular excitation, the scattering effect saturates due to the limited capacity of the molecule to absorb and radiate energy once the excited and ground states are equally populated.

Published
2009

254. Time-dependent wave-packet method for the complete determination of S-matrix elements for reactive molecular collisions in three dimensions

Author

Donald J. Kouri, Daniel Neuhauser, Richard S. Judson, and Michael Baer

Subjects
Physics, Wave propagation, Scattering, Wave packet, Atomic and Molecular Physics, and Optics, Schrödinger equation, Computational physics, symbols.namesake, Classical mechanics, symbols, Initial value problem, Scattering theory, Wave function, S-matrix
Abstract

An alternative time-dependent wave-packet method for treating three-dimensional gas phase reactive atom-diatom collisions is presented. The method employs a nonreactive body-frame wave packet propagation procedure, made possible by judicious use of absorbing optical potentials, a novel scheme for interpolating the wave function from coordinates in one arrangement to those in another and the fact that the time-dependent Schroedinger equation is an initial-value problem. The last feature makes possible a computationally viable and accurate procedure for changing from one arrangement's coordinates to another. In addition, the method allows the determination of S-matrix elements over a wide range of energies from a single wave-packet propagation. The method is illustrated by carrying out detailed calculations of inelastic and reactive scattering in the H + H2 system using the Liu-Siegbahn-Truhlar-Horowitz potential surface.

Published
1990

255. Molecular nanopolaritonics: Cross manipulation of near-field plasmons and molecules. I. Theory and application to junction control

Author

Kenneth Lopata and Daniel Neuhauser

Subjects
Density matrix, Condensed matter physics, Chemistry, Surface plasmon, Physics::Optics, General Physics and Astronomy, Resonance (particle physics), Molecular physics, Dipole, Quasiparticle, Polariton, Physical and Theoretical Chemistry, Random phase approximation, Plasmon
Abstract

Near-field interactions between plasmons and molecules are treated in a simple unified approach. The density matrix of a molecule is treated with linear-response random phase approximation and the plasmons are treated classically. The equations of motion for the combined system are linear, governed by a simple Liouvillian operator for the polariton (plasmon+molecule excitation) dynamics. The dynamics can be followed in time or directly in frequency space where a trace formula for the transmission is presented. A model system is studied, metal dots in a forklike arrangement, coupled to a two level system with a large transition-dipole moment. A Fano-type resonance [Phys. Rev. 103, 1202 (1956)] develops when the molecular response is narrower than the width of the absorption spectrum for the plasmons. We show that the direction of the dipole of the molecule determines the direction the polariton chooses. Further, the precise position of the molecule has a significant effect on the transfer.

Published
2007

256. Theoretical studies of molecular scale near-field electron dynamics

Author

Roi Baer and Daniel Neuhauser

Subjects
Coupling (physics), Electron transfer, Chemistry, Chemical physics, General Physics and Astronomy, Density functional theory, Electronic structure, Electron, Physical and Theoretical Chemistry, Atomic physics, Adiabatic process, Spectroscopy, Electromagnetic radiation
Abstract

Near-field scanning microscopy and nonlinear spectroscopy on a molecular scale involve weakly interacting subsystems that dynamically exchange electrons and electromagnetic energy. The theoretical description of such processes requires unified approach to the electron-near-field dynamics. By considering electronic structure and dynamics of two distant clusters or atoms we show that adiabatic local spin-density approximation (ALSDA) fails to describe (even qualitatively) essential details of electron dynamics in weakly interacting systems. A recently developed functional addresses these ailments within a time-dependent setting. With this method we study the spectroscopy of a composite system, namely, two weakly coupled metallic clusters. The near-field (dipole-dipole) coupling and electron transfer display an interesting interplay, producing exponential sensitivity of emission yield to the intercomponent distance.

Published
2006

257. On the stability of glycine-water clusters with excess electron: Implications for photoelectron spectroscopy

Author

Sungyul Lee, Ae-Ri Kang, Doo-Sik Ahn, Sang Kyu Kim, Bongsoo Kim, and Daniel Neuhauser

Subjects
Models, Molecular, Light, Photochemistry, Glycine, Molecular Conformation, General Physics and Astronomy, Electrons, Ion, Motion, chemistry.chemical_compound, Computational chemistry, Electrochemistry, Molecule, Computer Simulation, Physical and Theoretical Chemistry, Conformational isomerism, Chemistry, Hydrogen bond, Spectrum Analysis, Water, Hydrogen Bonding, Solutions, Crystallography, Models, Chemical, Zwitterion, Chemical stability, Isomerization
Abstract

Calculations are presented for the glycine-(H(2)O)(n) (-) (n=0-2) anionic clusters with excess electron, with the glycine core in the canonical or zwitterion form. A variety of conformers are predicted, and their relative energy is examined to estimate thermodynamic stability. The dynamic (proton transfer) pathways between the anionic clusters with the canonical and the zwitterion glycine core are examined. Small barrier heights for isomerization from the zwitterion glycine-(H(2)O)(2) (-) anion to those with canonical glycine core suggest that the former conformers may be kinetically unstable and unfavorable for detection of neutral glycine zwitterion-(H(2)O)(n) (n=1,2) clusters by photodetachment, in accordance with the photoelectron spectroscopic experiments by Bowen and co-workers [Xu et al., J. Chem. Phys. 119, 10696 (2003)]. The calculated stability of the glycine-(H(2)O)(n) (-) anion clusters with canonical glycine core relative to those with zwitterion core indicates that the observation of the anionic conformers with the canonical glycine core would be much more feasible, as revealed by Johnson and co-workers [Diken et al. J. Chem. Phys. 120, 9902 (2004)].

Published
2005

258. Effect of the second-derivative paraxial term in the scalar Maxwell's equation on amplitude losses and reflections in optical fibers

Author

Ilya Vorobeichik, Nimrod Moiseyev, and Daniel Neuhauser

Subjects
Physics, Amplitude, Classical mechanics, Scattering, Paraxial approximation, Scalar (mathematics), Reflection (physics), Single-mode optical fiber, Physics::Optics, Light beam, Statistical and Nonlinear Physics, Atomic and Molecular Physics, and Optics, Term (time)
Abstract

The scalar Maxwell's equation, including the often-neglected second-derivative paraxial term, is solved. This term is shown to increase the loss of the amplitude of the light beam inside a single-mode optical fiber. The reflected (backward-traveling) wave that is due to the second-derivative term is obtained from the calculation of the scattering matrix as formulated in quantum-mechanical dynamical problems.

Published
1997

262. A new accurate (time-independent) method for treating reactive collisions: conversion of a scattering problem into a bound problem

Author

Michael Baer, Daniel Neuhauser, and Yuval Oreg

Subjects
Work (thermodynamics), Computational chemistry, Chemistry, Scattering, Flux, Physics::Chemical Physics, Physical and Theoretical Chemistry, Computational physics
Abstract

This work describes a new (time-independent) approach to the study of atom–diatom reactive collisions in the collinear case and in three dimensions. The method is based on the idea of converting a reactive multi-arrangement problem into an inelastic single-arrangement problem. This conversion is done by applying optical potentials which are located at all exits of the reagents arrangement. The reactive transition probabilities are calculated applying flux formulae. The method is reminiscent of a previous time-dependent method that was successfully applied for both collinear and three-dimensional reactive collisions.

Published
1990

263. Bremsstrahlung in heavy ion collisions

Author

Steven E. Koonin and Daniel Neuhauser

Subjects
Physics, Nuclear physics, Nuclear and High Energy Physics, Photon, Photon emission, Astrophysics::High Energy Astrophysical Phenomena, Bremsstrahlung, Heavy ion, Nuclear Experiment, Nuclear matter, Spectral line
Abstract

We calculate photon emission spectra from nuclear matter in the incoherent limit and combine them with a simplified fireball model to predict photon production cross sections in heavy ion collisions. The spectra differ from previous estimates based on a classical soft-photon approximation and lead to good agreement with experiment.

Published
1987

264. Structure of matter in strong magnetic fields

Author

K. Langanke, Steven E. Koonin, and Daniel Neuhauser

Subjects
Physics, Surface (mathematics), Neutron star, chemistry, Atom, Structure (category theory), chemistry.chemical_element, Physics::Atomic Physics, Atomic physics, Caltech Library Services, Helium, Magnetic field
Abstract

We give a detailed presentation of Hartree-Fock calculations of atoms and molecular chains in 10^12 G magnetic fields, as are supposed to exist on the surface of neutron stars. These calculations are the first self-consistent ones treating exchange properly for atoms heavier than helium in high fields. We find that the isolated atom is energetically favored over molecular chains for Z>2 at fields greater than 1×10^12G and for Z>4 at fields greater than 5×10^12 G. These results indicate that matter on the surface of neutron stars is bound very weakly, if at all.

Published
1987

265. The application of wave packets to reactive atom–diatom systems: A new approach

Author

Daniel Neuhauser and Michael Baer

Subjects
Formalism (philosophy of mathematics), symbols.namesake, Chemical reaction kinetics, Chemistry, Quantum mechanics, Wave packet, Hydrogen molecule, symbols, General Physics and Astronomy, Physical and Theoretical Chemistry, Collision, Diatomic molecule, Schrödinger equation
Abstract

This work describes a new approach for the study of atom–diatom reactive collision employing the time‐dependent wave packet Schrodinger equation. The method makes use of the projection operator formalism to form a coupled system of time dependent Schrodinger equations and of optical potentials to circumvent the necessary use of products coordinates. Two versions are presented. As an example we applied the method to the collinear reactive H+H2 system for which are calculated both transition probabilities and rate constants.

Published
1989

266. Photon interferometry for heavy ion collisions

Author

Daniel Neuhauser

Subjects
Physics, Nuclear and High Energy Physics, Interferometry, Photon, Nuclear Theory, Hanbury Brown and Twiss effect, Heavy ion, Atomic physics, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, Nuclear Experiment, Polarization (waves)
Abstract

The Hanbury-Brown-Twiss correlation of high-energy photons emitted from heavy ion collisions is studied and it is found that both the polarization average and a possible coherent component complicate the extraction of the size and lifetime of the emitting source from the correlation function.

Published
1986

267. Time dependent three‐dimensional body frame quantal wave packet treatment of the H+H2 exchange reaction on the Liu–Siegbahn–Truhlar–Horowitz (LSTH) surface

Author

Richard S. Judson, Donald J. Kouri, Michael Baer, and Daniel Neuhauser

Subjects
Surface (mathematics), Angular momentum, Wave propagation, Scattering, Chemistry, Wave packet, General Physics and Astronomy, Physical and Theoretical Chemistry, Atomic physics, Diatomic molecule, Quantum chemistry, Quantum
Abstract

The first successful application of the three-dimensional quantum body frame wave packet approach to reactive scattering is reported for the H + H2 exchange reaction on the LSTH potential surface. The method used is based on a procedure for calculating total reaction probabilities from wave packets. It is found that converged, vibrationally resolved reactive probabilities can be calculated with a grid that is not much larger than required for the pure inelastic calculation. Tabular results are presented for several energies.

Published
1989

268. Arrangement channel approach to exchange processes: Quasisymmetric and symmetric representations

Author

Daniel Neuhauser and Michael Baer

Subjects
Physics, Many-body problem, Nuclear and High Energy Physics, Matrix (mathematics), Partial differential equation, Differential equation, Independent equation, Simultaneous equations, Quantum mechanics, Mathematical analysis, Integral equation, S-matrix
Abstract

In this work are presented two new sets of integral equations for studying three-body exchange processes. The two are obtained from the Baer-Kouri-Levin-Tobocman approach by assuming the W matrix, via which the coupling is done, to be dependent on the internal coordinates of the system. In contrast to the channel permuting array structure of the original version of the Baer-Kouri-Levin-Tobocman equations, one set of equations is almost symmetric with respect to the different channels and the other is fully symmetric, thus ensuring a unitary S matrix. The first set of equations has already been solved for a three-channel, three-dimensional system, H+H/sub 2/ (J = 0), and has been found to yield the correct results. Connectivity, as related to these equations, is discussed.

Published
1988

269. Hartree-Fock calculations of atoms and molecular chains in strong magnetic fields

Author

Karlheinz Langanke, Daniel Neuhauser, and Steven E. Koonin

Subjects
Physics, Chain (algebraic topology), Binding energy, Atom, Hartree–Fock method, Physics::Atomic and Molecular Clusters, Nuclear binding energy, Field strength, Physics::Atomic Physics, Atomic physics, Ground state, Caltech Library Services, Magnetic field
Abstract

We calculate the binding energies of atoms and molecular chains in 10^12 G magnetic fields using the Hartree-Fock method. For Z>2 (4) at 1×10^12 (5×10^12), the isolated atom is energetically favored over the molecular chain.

Published
1986

272. Highly Excited Molecules

Author

AMY S. MULLIN, GEORGE C. SCHATZ, Daniel Neuhauser, Jörg Main, Christof Jung, Howard S. Taylor, William F. Polik, J. Ruud van Ommen, David S. Perry, Dmitrii V. Shalashilin, Donald L. Thompson, D. A. Blunt, A. G. Suits, James D. Chesko, Yuan T. Lee, Paul J. Dagdigian, Xin Yang, Eunsook Hwang, George W. Flynn, Chris A. Michaels, H. Charles Tapalian, Zhen Lin, Eric T. Sevy, Mark A. Muyskens, Jianxin Qi, Max Dyksterhouse, Joel M. Bowman, Marcel Drabbels, Alec M. Wodtke, Derek R. McDowell, Fei Wu, R. Bruce Weisman, György Lendvay, Toshiyuki Takayanagi, John R. Barker, Samuel M. Clegg, Brian D. Gilbert, Shao-ping Lu, Charles S. Parmenter, V. Bernshtein, I. Oref, Hai-Lung Dai, W. L. Hase, P. de Sainte Claire, A. Sanov, D. W. Arnold, M. Korolik, H. Ferkel, C. R. Bieler, C. Capellos, C. Wittig, Hanna Reisler, Ward H. Thompson, AMY S. MULLIN, GEORGE C. SCHATZ, Daniel Neuhauser, Jörg Main, Christof Jung, Howard S. Taylor, William F. Polik, J. Ruud van Ommen, David S. Perry, Dmitrii V. Shalashilin, Donald L. Thompson, D. A. Blunt, A. G. Suits, James D. Chesko, Yuan T. Lee, Paul J. Dagdigian, Xin Yang, Eunsook Hwang, George W. Flynn, Chris A. Michaels, H. Charles Tapalian, Zhen Lin, Eric T. Sevy, Mark A. Muyskens, Jianxin Qi, Max Dyksterhouse, Joel M. Bowman, Marcel Drabbels, Alec M. Wodtke, Derek R. McDowell, Fei Wu, R. Bruce Weisman, György Lendvay, Toshiyuki Takayanagi, John R. Barker, Samuel M. Clegg, Brian D. Gilbert, Shao-ping Lu, Charles S. Parmenter, V. Bernshtein, I. Oref, Hai-Lung Dai, W. L. Hase, P. de Sainte Claire, A. Sanov, D. W. Arnold, M. Korolik, H. Ferkel, C. R. Bieler, C. Capellos, C. Wittig, Hanna Reisler, and Ward H. Thompson

Published
1997

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