2,194 research outputs found
Polarons in highly doped atomically thin graphitic materials
Polaron spectral functions are computed for highly doped
graphene-on-substrate and other atomically thin graphitic systems using the
diagrammatic Monte Carlo technique. The specific aim is to investigate the
effects of interaction on spectral functions when the symmetry between
sub-lattices of a honeycomb lattice has been broken by the substrate or
ionicity, inducing a band gap. Introduction of electron-phonon coupling leads
to several polaronic features, such as band-flattening and changes in particle
lifetimes. At the K point, differences between energies on each sub-lattice
increase with electron-phonon coupling, indicating an augmented transport gap,
while the spectral gap decreases slightly. Effects of phonon dispersion and
long-range interactions are investigated, and found to lead to only
quantitative changes in spectra
Electron and phonon dispersions of the two dimensional Holstein model: Effects of vertex and non-local corrections
I apply the newly developed dynamical cluster approximation (DCA) to the
calculation of the electron and phonon dispersions in the two dimensional
Holstein model. In contrast to previous work, the DCA enables the effects of
spatial fluctuations (non-local corrections) to be examined. Approximations
neglecting and incorporating lowest-order vertex corrections are investigated.
I calculate the phonon density of states, the renormalised phonon dispersion,
the electron dispersion and electron spectral functions. I demonstrate how
vertex corrections stabilise the solution, stopping a catastrophic softening of
the phonon mode. A kink in the electron dispersion is found in the
normal state along the symmetry direction in both the vertex-
and non-vertex-corrected theories for low phonon frequencies, corresponding
directly to the renormalised phonon frequency at the point. This kink
is accompanied by a sudden drop in the quasi-particle lifetime. Vertex and
non-local corrections enhance the effects at large bare phonon frequencies.Comment: I am posting reprints of the final submitted versions of previous
articles to improve access. Here ARPES "kinks" are discussed. Article was
published in 2003. 17 pages, 9 figure
Breakdown of Migdal--Eliashberg theory via catastrophic vertex divergence at low phonon frequency
We investigate the applicability of Migdal--Eliashberg (ME) theory by
revisiting Migdal's analysis within the dynamical mean-field theory framework.
First, we compute spectral functions, the quasi-particle weight, the self
energy, renormalised phonon frequency and resistivity curves of the half-filled
Holstein model. We demonstrate how ME theory has a phase-transition-like
instability at intermediate coupling, and how the Engelsberg--Schrieffer (ES)
picture is complicated by low-energy excitations from higher order diagrams
(demonstrating that ES theory is a very weak coupling approach). Through
consideration of the lowest-order vertex correction, we analyse the
applicability of ME theory close to this transition. We find a breakdown of the
theory in the intermediate coupling adiabatic limit due to a divergence in the
vertex function. The region of applicability is mapped out, and it is found
that ME theory is only reliable in the weak coupling adiabatic limit, raising
questions about the accuracy of recent analyses of cuprate superconductors
which do not include vertex corrections.Comment: 19 pages, 10 figures, accepted for publication in Journal of Low
Temperature Physic
Quantum simulation of electron-phonon interactions in strongly deformable materials
We propose an approach for quantum simulation of electron-phonon interactions
using Rydberg states of cold atoms and ions. We show how systems of cold atoms
and ions can be mapped onto electron-phonon systems of the Su-Schrieffer-Heeger
type. We discuss how properties of the simulated Hamiltonian can be tuned and
how to read physically relevant properties from the simulator. In particular,
use of painted spot potentials offers a high level of tunability, enabling all
physically relevant regimes of the electron-phonon Hamiltonian to be accessed.Comment: To appear in New Journal of Physic
Exploiting the Design Freedom of RM
This paper details how Rapid Manufacturing (RM) can overcome the restrictions imposed by the
inherent process limitations of conventional manufacturing techniques and become the enabling
technology in fabricating optimal products. A new design methodology capable of exploiting
RMтАЩs increased design freedom is therefore needed. Inspired by natural world structures of trees
and bones, a multi-objective, genetic algorithm based topology optimisation approach is
presented. This combines multiple unit cell structures and varying volume fractions to create a
heterogeneous part structure which exhibits a uniform stress distribution.Mechanical Engineerin
PCSYS: The optimal design integration system picture drawing system with hidden line algorithm capability for aerospace vehicle configurations
A vehicle geometric definition based upon quadrilateral surface elements to produce realistic pictures of an aerospace vehicle. The PCSYS programs can be used to visually check geometric data input, monitor geometric perturbations, and to visualize the complex spatial inter-relationships between the internal and external vehicle components. PCSYS has two major component programs. The between program, IMAGE, draws a complex aerospace vehicle pictorial representation based on either an approximate but rapid hidden line algorithm or without any hidden line algorithm. The second program, HIDDEN, draws a vehicle representation using an accurate but time consuming hidden line algorithm
Statistical physics of cerebral embolization leading to stroke
We discuss the physics of embolic stroke using a minimal model of emboli
moving through the cerebral arteries. Our model of the blood flow network
consists of a bifurcating tree, into which we introduce particles (emboli) that
halt flow on reaching a node of similar size. Flow is weighted away from
blocked arteries, inducing an effective interaction between emboli. We justify
the form of the flow weighting using a steady flow (Poiseuille) analysis and a
more complicated nonlinear analysis. We discuss free flowing and heavily
congested limits and examine the transition from free flow to congestion using
numerics. The correlation time is found to increase significantly at a critical
value, and a finite size scaling is carried out. An order parameter for
non-equilibrium critical behavior is identified as the overlap of blockages'
flow shadows. Our work shows embolic stroke to be a feature of the cerebral
blood flow network on the verge of a phase transition.Comment: 11 pages, 11 figures. Major rewrite including improved justification
of the model and a finite size scalin
<i>d</i>-wave superconductivity from electron-phonon interactions
I examine electron-phonon mediated superconductivity in the intermediate coupling and phonon frequency regime of the quasi-two-dimensional Holstein model. I use an extended Migdal-Eliashberg theory that includes vertex corrections and spatial fluctuations. I find a d-wave superconducting state that is unique close to half filling. The order parameter undergoes a transition to s-wave superconductivity on increasing filling. I explain how the inclusion of both vertex corrections and spatial fluctuations is essential for the prediction of a d-wave order parameter. I then discuss the effects of a large Coulomb pseudopotential on the superconductivity (such as is found in contemporary superconducting materials like the cuprates), which results in the destruction of the s-wave states, while leaving the d-wave states unmodified
Tunable graphene bandgaps from superstrate mediated interactions
A theory is presented for the strong enhancement of graphene-on-substrate
bandgaps by attractive interactions mediated through phonons in a polarizable
superstrate. It is demonstrated that gaps of up to 1eV can be formed for
experimentally achievable values of electron-phonon coupling and phonon
frequency. Gap enhancements range between 1 and 4, indicating possible benefits
to graphene electronics through greater bandgap control for digital
applications, lasers, LEDs and photovoltaics through the relatively simple
application of polarizable materials such as SiO2 and Si3N4.Comment: 4 pages, 4 figures, to appear in Phys. Rev.
Recommended from our members
Rapid Manufactured Textiles
Rapid Manufacturing (RM) is increasingly becoming a viable manufacturing process due
to dramatic advantages that are achievable in the area of design complexity. Through the
exploration of the design freedom, this paper introduces the concept of manufacturing textiles for
potential smart and high performance textile applications. This paper discusses the current
limitations associated with the manufacture of textiles through RM and presents a novel
methodology for the generation of 3D conformal RM textile articles. The paper concludes that
through RM it is entirely possible to manufacture a structure that incorporates drape and free
movement properties directly comparable to conventional textiles.Mechanical Engineerin
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