2,327 research outputs found
Pomeranchuk Instability in a non-Fermi Liquid from Holography
The Pomeranchuk instability, in which an isotropic Fermi surface distorts and
becomes anisotropic due to strong interactions, is a possible mechanism for the
growing number of experimental systems which display transport properties that
differ along the and axes. We show here that the gauge-gravity duality
can be used to describe such an instability in fermionic systems. Our
holographic model consists of fermions in a background which describes the
causal propagation of a massive neutral spin-two field in an asymptotically AdS
spacetime. The Fermi surfaces in the boundary theory distort spontaneously and
become anisotropic once the neutral massive spin-two field develops a
normalizable mode in the bulk. Analysis of the fermionic correlators reveals
that the low-lying fermionic excitations are non-Fermi liquid-like both before
and after the Fermi surface shape distortion. Further, the spectral weight
along the Fermi surface is angularly dependent and can be made to vanish along
certain directions.Comment: Updated version to appear in PRD. New version has WKB analysis of
spectral intensity in ordered phas
Issues for computer modelling of room acoustics in non-concert hall settings
The basic principle of common room acoustics computer models is the energy-based geometrical room acoustics theory. The energy-based calculation relies on the averaging effect provided when there are many reflections from many different directions, which is well suited for large concert halls at medium and high frequencies. In recent years computer modelling has become an established tool in architectural acoustics design thanks to the advance in computing power and improved understanding of the modelling accuracy. However concert hall is only one of many types of built environments that require good acoustic design. Increasingly computer models are being sought for non-concert hall applications, such as in small rooms at low frequencies, flat rooms in workplace surroundings, and long enclosures such as underground stations. In these built environments the design issues are substantially difference from that of concert halls and in most cases the common room acoustics models will needed to be modified or totally re-formulated in order to deal with these new issues. This paper looks at some examples of these issues. In workplace environments we look at the issues of directional propagation and volume scattering by furniture and equipment instead of the surface scattering that is common assumed in concert hall models. In small rooms we look at the requirement of using wave models, such as boundary element models, or introducing phase information into geometrical room acoustics models to determine wave behaviours. Of particular interest is the ability of the wave models to provide phase information that is important not only for room modes but for the construction of impulse response for auralisation. Some simulated results using different modelling techniques will be presented to illustrate the problems and potential solutions
Examination of the relationship between essential genes in PPI network and hub proteins in reverse nearest neighbor topology
Abstract Background In many protein-protein interaction (PPI) networks, densely connected hub proteins are more likely to be essential proteins. This is referred to as the "centrality-lethality rule", which indicates that the topological placement of a protein in PPI network is connected with its biological essentiality. Though such connections are observed in many PPI networks, the underlying topological properties for these connections are not yet clearly understood. Some suggested putative connections are the involvement of essential proteins in the maintenance of overall network connections, or that they play a role in essential protein clusters. In this work, we have attempted to examine the placement of essential proteins and the network topology from a different perspective by determining the correlation of protein essentiality and reverse nearest neighbor topology (RNN). Results The RNN topology is a weighted directed graph derived from PPI network, and it is a natural representation of the topological dependences between proteins within the PPI network. Similar to the original PPI network, we have observed that essential proteins tend to be hub proteins in RNN topology. Additionally, essential genes are enriched in clusters containing many hub proteins in RNN topology (RNN protein clusters). Based on these two properties of essential genes in RNN topology, we have proposed a new measure; the RNN cluster centrality. Results from a variety of PPI networks demonstrate that RNN cluster centrality outperforms other centrality measures with regard to the proportion of selected proteins that are essential proteins. We also investigated the biological importance of RNN clusters. Conclusions This study reveals that RNN cluster centrality provides the best correlation of protein essentiality and placement of proteins in PPI network. Additionally, merged RNN clusters were found to be topologically important in that essential proteins are significantly enriched in RNN clusters, and biologically important because they play an important role in many Gene Ontology (GO) processes.http://deepblue.lib.umich.edu/bitstream/2027.42/78257/1/1471-2105-11-505.xmlhttp://deepblue.lib.umich.edu/bitstream/2027.42/78257/2/1471-2105-11-505-S1.DOChttp://deepblue.lib.umich.edu/bitstream/2027.42/78257/3/1471-2105-11-505.pdfPeer Reviewe
A New Class of Solutions to the Strong CP Problem with a Small Two-Loop theta
We present a new class of models which produce zero theta (QCD} angle at the
tree and one-loop level due to hermiticity of sub-blocks in the extended quark
mass matrices. The structure can be maintained typically by non-abelian
generation symmetry. Two examples are given for this class of solutions.Comment: 4 pages, 2 figure
Pulse confinement in optical fibers with random dispersion
Short range correlated uniform noise in the dispersion coefficient, inherent
in many types of optical fibers, broadens and eventually destroys all initially
ultra-short pulses. However, under the constraint that the integral of the
random component of the dispersion coefficient is set to zero, or pinned,
periodically or quasi-periodically along the fiber, the nature of the pulse
propagation changes dramatically. For the case that randomness is added to
constant positive dispersion, the pinning restriction significantly reduces
pulse broadening. If the randomness is added to piecewise constant periodic
dispersion, the pinning may even provide probability distributions of pulse
parameters that are numerically indistinguishable from the statistically steady
case. The pinning method can be used to both manufacture better fibers and
upgrade existing fiber links.Comment: 4 pages, 2 figure
Dynamics of Solitons and Quasisolitons of Cubic Third-Order Nonlinear Schr\"odinger Equation
The dynamics of soliton and quasisoliton solutions of cubic third order
nonlinear Schr\"{o}dinger equation is studied. The regular solitons exist due
to a balance between the nonlinear terms and (linear) third order dispersion;
they are not important at small ( is the coefficient in
the third derivative term) and vanish at . The most essential,
at small , is a quasisoliton emitting resonant radiation (resonantly
radiating soliton). Its relationship with the other (steady) quasisoliton,
called embedded soliton, is studied analytically and in numerical experiments.
It is demonstrated that the resonantly radiating solitons emerge in the course
of nonlinear evolution, which shows their physical significance
Differences in the Sub-seasonal Predictability of Extreme Stratospheric Events
Extreme stratospheric events such as sudden stratospheric warming (SSW) and strong vortex events can have downward impacts on surface weather that can last for several weeks to months. Hence, successful predictions of these stratospheric events can be beneficial for extendedrange weather prediction. However, the predictability of extreme stratospheric events is most often limited to around 2 weeks or less. The predictability strongly differs within events of the same type and also between event types. The reasons for the observed differences in the predictability, however, are not resolved. We extend the analysis of the predictability of stratospheric extreme events to include wind deceleration and acceleration events, with SSW and strong vortex events as subsets, to conduct a systematic comparison of sub-seasonal predictability between events in the European Centre for Medium-Range Weather Forecasts (ECMWF) prediction system. Events of stronger magnitude are found to be less predictable than weaker events for both wind deceleration and acceleration events, with both types of events showing a close to linear dependence of predictability on event magnitude. There are, however, deviations from this linear behaviour for very strong magnitude events. The difficulties of the prediction system in predicting extremely strong anomalies can be traced to a poor predictability of extreme wave activity fluxes in the lower stratosphere, which impacts the prediction of deceleration events and, interestingly, also acceleration events. Our study suggests that improvements in the understanding of the wave amplification that is associated with extremely strong wave activity fluxes and accurately representing these processes in the model are expected to enhance the predictability of stratospheric extreme events and, by extension, their impacts on surface weather and climate.ISSN:2698-4016ISSN:2698-400
- …