54,425 research outputs found
On finite element implementation and computational techniques for constitutive modeling of high temperature composites
The research work performed during the past year on finite element implementation and computational techniques pertaining to high temperature composites is outlined. In the present research, two main issues are addressed: efficient geometric modeling of composite structures and expedient numerical integration techniques dealing with constitutive rate equations. In the first issue, mixed finite elements for modeling laminated plates and shells were examined in terms of numerical accuracy, locking property and computational efficiency. Element applications include (currently available) linearly elastic analysis and future extension to material nonlinearity for damage predictions and large deformations. On the material level, various integration methods to integrate nonlinear constitutive rate equations for finite element implementation were studied. These include explicit, implicit and automatic subincrementing schemes. In all cases, examples are included to illustrate the numerical characteristics of various methods that were considered
Finite element implementation of state variable-based viscoplasticity models
The implementation of state variable-based viscoplasticity models is made in a general purpose finite element code for structural applications of metals deformed at elevated temperatures. Two constitutive models, Walker's and Robinson's models, are studied in conjunction with two implicit integration methods: the trapezoidal rule with Newton-Raphson iterations and an asymptotic integration algorithm. A comparison is made between the two integration methods, and the latter method appears to be computationally more appealing in terms of numerical accuracy and CPU time. However, in order to make the asymptotic algorithm robust, it is necessary to include a self adaptive scheme with subincremental step control and error checking of the Jacobian matrix at the integration points. Three examples are given to illustrate the numerical aspects of the integration methods tested
Spin states and persistent currents in mesoscopic rings: spin-orbit interactions
We investigate theoretically electron spin states in one dimensional (1D) and
two dimensional (2D) hard-wall mesoscopic rings in the presence of both the
Rashba spin-orbit interaction (RSOI) and the Dresselhaus spin-orbit interaction
(DSOI) in a perpendicular magnetic field. The Hamiltonian of the RSOI alone is
mathematically equivalent to that of the DSOI alone using an SU(2) spin
rotation transformation. Our theoretical results show that the interplay
between the RSOI and DSOI results in an effective periodic potential, which
consequently leads to gaps in the energy spectrum. This periodic potential also
weakens and smoothens the oscillations of the persistent charge current (CC)
and spin current (SC) and results in the localization of electrons. For a 2D
ring with a finite width, higher radial modes destroy the periodic oscillations
of persistent currents.Comment: 12 pages, 14 figure
Junctions of multiple quantum wires with different Luttinger parameters
Within the framework of boundary conformal field theory, we evaluate the
conductance of stable fixed points of junctions of two and three quantum wires
with different Luttinger parameters. For two wires, the physical properties are
governed by a single effective Luttinger parameters for each of the charge and
spin sectors. We present numerical density-matrix-renormalization-group
calculations of the conductance of a junction of two chains of interacting
spinless fermions with different interaction strengths, obtained using a
recently developed method [Phys. Rev. Lett. 105, 226803 (2010)]. The numerical
results show very good agreement with the analytical predictions. For three
spinless wires, i.e., a Y junction, we analytically determine the full phase
diagram, and compute all fixed-point conductances as a function of the three
Luttinger parameters.Comment: 13 pages, 6 figure
How to find conductance tensors of quantum multi-wire junctions through static calculations: application to an interacting Y-junction
Conductance is related to dynamical correlation functions which can be
calculated with \textit{time-dependent} methods. Using boundary conformal field
theory, we relate the conductance tensors of quantum junctions of multiple
wires to static correlation functions in a finite system. We then propose a
general method for determining the conductance through
\textit{time-independent} calculations alone. Applying the method to a
Y-junction of interacting quantum wires, we numerically verify the theoretical
prediction for the conductance of the chiral fixed-point of the Y-junction and
then calculate the thus far unknown conductance of its M fixed point with
time-independent density matrix renormalization group method.Comment: 4 pages, 2 figures, final published versio
Larkin-Ovchinnikov-Fulde-Ferrell phase in the superconductor (TMTSF)2ClO4: Theory versus experiment
We consider a formation of the Larkin-Ovchinnikov-Fulde-Ferrell (LOFF) phase
in a quasi-one-dimensional (Q1D) conductor in a magnetic field, parallel to its
conducting chains, where we take into account both the paramagnetic
spin-splitting and orbital destructive effects against superconductivity. We
show that, due to a relative weakness of the orbital effects in a Q1D case, the
LOFF phase appears in (TMTSF)ClO superconductor for real values of its
Q1D band parameters. We compare our theoretical calculations with the recent
experimental data by Y. Maeno's group [S. Yonezawa et al., Phys. Rev. Lett.
\textbf{100}, 117002 (2008)] and show that there is a good qualitative and
quantitative agreement between the theory and experimental data.Comment: 4 pages, 1 figur
Surface electronic structure of a topological Kondo insulator candidate SmB6: insights from high-resolution ARPES
The Kondo insulator SmB6 has long been known to exhibit low temperature (T <
10K) transport anomaly and has recently attracted attention as a new
topological insulator candidate. By combining low-temperature and high
energy-momentum resolution of the laser-based ARPES technique, for the first
time, we probe the surface electronic structure of the anomalous conductivity
regime. We observe that the bulk bands exhibit a Kondo gap of 14 meV and
identify in-gap low-lying states within a 4 meV window of the Fermi level on
the (001)-surface of this material. The low-lying states are found to form
electron-like Fermi surface pockets that enclose the X and the Gamma points of
the surface Brillouin zone. These states disappear as temperature is raised
above 15K in correspondence with the complete disappearance of the 2D
conductivity channels in SmB6. While the topological nature of the in-gap
metallic states cannot be ascertained without spin (spin-texture) measurements
our bulk and surface measurements carried out in the
transport-anomaly-temperature regime (T < 10K) are consistent with the
first-principle predicted Fermi surface behavior of a topological Kondo
insulator phase in this material.Comment: 4 Figures, 6 Page
Nodeless superconductivity in the cage-type superconductor Sc5Ru6Sn18 with preserved time-reversal symmetry
We report the single-crystal synthesis and detailed investigations of the
cage-type superconductor Sc5Ru6Sn18, using powder x-ray diffraction (XRD),
magnetization, specific-heat and muon-spin relaxation (muSR) measurements.
Sc5Ru6Sn18 crystallizes in a tetragonal structure (space group I41/acd) with
the lattice parameters a = 1.387(3) nm and c = 2.641(5) nm. Both DC and AC
magnetization measurements prove the type-II superconductivity in Sc5Ru6Sn18
with Tc = 3.5(1) K, a lower critical field H_c1 (0) = 157(9) Oe and an upper
critical field, H_c2 (0) = 26(1) kOe. The zero-field electronic specific-heat
data are well fitted using a single-gap BCS model, with superconducting gap =
0.64(1) meV. The Sommerfeld constant varies linearly with the applied magnetic
field, indicating s-wave superconductivity in Sc5Ru6Sn18. Specific-heat and
transverse-field (TF) muSR measurements reveal that Sc5Ru6Sn18 is a
superconductor with strong electron-phonon coupling, with TF-muSR also
suggesting the single-gap s-wave character of the superconductivity.
Furthermore, zero-field muSR measurements do not detect spontaneous magnetic
fields below Tc, hence implying that time-reversal symmetry is preserved in
Sc5Ru6Sn18.Comment: 23 pages, 11 figure
Gauge Unification and Quark Masses in a Pati-Salam Model from Branes
We investigate the phase space of parameters in the Pati-Salam model derived
in the context of D-branes scenarios, requiring low energy string scale. We
find that a non-supersymmetric version complies with a string scale as low as
10 TeV, while in the supersymmetric version the string scale raises up to ~2 x
10^7 TeV. The limited energy region for RGE running demands a large tan(beta)
in order to have experimentally acceptable masses for the top and bottom
quarks.Comment: 11 pages, LaTeX, 7 figures include
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