3,544 research outputs found
High-Field Electrical Transport in Single-Wall Carbon Nanotubes
Using low-resistance electrical contacts, we have measured the intrinsic
high-field transport properties of metallic single-wall carbon nanotubes.
Individual nanotubes appear to be able to carry currents with a density
exceeding 10^9 A/cm^2. As the bias voltage is increased, the conductance drops
dramatically due to scattering of electrons. We show that the current-voltage
characteristics can be explained by considering optical or zone-boundary phonon
emission as the dominant scattering mechanism at high field.Comment: 4 pages, 3 eps figure
Right-Handed New Physics Remains Strangely Beautiful
Current data on CP violation in B_d -> eta' K_S and B_d -> phi K_S, taken
literally, suggest new physics contributions in b -> s transitions. Despite a
claim to the contrary, we point out that right-handed operators with a single
weak phase can account for both deviations thanks to the two-fold ambiguity in
the extraction of the weak phase from the corresponding CP-asymmetry. This
observation is welcome since large mixing in the right-handed sector is favored
by many GUT models and frameworks which address the flavor puzzle. There are
also interesting correlations with the B_s system which provide a way to test
this scenario in the near future.Comment: 7 pages, 9 figures; published version: added 1 reference and 1
clarificatio
Mass spectrum of the scalar hidden charm and bottom tetraquark states
In this article, we study the mass spectrum of the scalar hidden charm and
bottom tetraquark states with the QCD sum rules. The numerical results are
compared with the corresponding ones from a relativistic quark model based on a
quasipotential approach in QCD. The relevant values from the constituent
diquark model based on the constituent diquark masses and the spin-spin
interactions are also discussed.Comment: 19 pages, 36 figures, slight revisio
Dynamic coexistence of various configurations: clusters vs.nuclei
The presence of energy shells in metallic clusters and atomic nuclei leads to
a peculiar relation between the number of particles N and the structure, and
this leads to a strong correlation between the energy spectrum and N. An
analysis of experimental data leads to the conclusion that, in addition to the
static Jahn-Teller effect, the dynamic effect leading to the quantum
coexistence of different configurations (quantum oscillations) plays an
important role. Such suggested coexistence is an essential feature of clusters
as well as nuclei, both finite Fermi systems.Comment: 6 pages, 2 figure
Dynamical electron transport through a nanoelectromechanical wire in a magnetic field
We investigate dynamical transport properties of interacting electrons moving
in a vibrating nanoelectromechanical wire in a magnetic field. We have built an
exactly solvable model in which electric current and mechanical oscillation are
treated fully quantum mechanically on an equal footing. Quantum mechanically
fluctuating Aharonov-Bohm phases obtained by the electrons cause nontrivial
contribution to mechanical vibration and electrical conduction of the wire. We
demonstrate our theory by calculating the admittance of the wire which are
influenced by the multiple interplay between the mechanical and the electrical
energy scales, magnetic field strength, and the electron-electron interaction
Asymptotic Nusselt numbers for internal flow in the Cassie state
We consider laminar, fully-developed, Poiseuille flows of liquid in the
Cassie state through diabatic, parallel-plate microchannels symmetrically
textured with isoflux ridges. Through the use of matched asymptotic expansions
we analytically develop expressions for (apparent hydrodynamic) slip lengths
and variously-defined Nusselt numbers. Our small parameter () is the
pitch of the ridges divided by the height of the microchannel. When the ridges
are oriented parallel to the flow, we quantify the error in the Nusselt number
expressions in the literature and provide a new closed-form result. The latter
is accurate to and valid for any solid (ridge)
fraction, whereas those in the current literature are accurate to
and breakdown in the important limit when solid
fraction approaches zero. When the ridges are oriented transverse to the
(periodically fully-developed) flow, the error associated with neglecting
inertial effects in the slip length is shown to be
, where is the channel-scale
Reynolds number based on its hydraulic diameter. The corresponding Nusselt
number expressions are new and their accuracy is shown to be dependent on
Reynolds number, Peclet number and Prandtl number in addition to .
Manipulating the solution to the inner temperature problem encountered in the
vicinity of the ridges shows that classic results for thermal spreading
resistance are better expressed in terms of polylogarithm functions.Comment: 41 pages, submitted to Journal of Fluid Mechanic
FLEET: Butterfly Estimation from a Bipartite Graph Stream
We consider space-efficient single-pass estimation of the number of
butterflies, a fundamental bipartite graph motif, from a massive bipartite
graph stream where each edge represents a connection between entities in two
different partitions. We present a space lower bound for any streaming
algorithm that can estimate the number of butterflies accurately, as well as
FLEET, a suite of algorithms for accurately estimating the number of
butterflies in the graph stream. Estimates returned by the algorithms come with
provable guarantees on the approximation error, and experiments show good
tradeoffs between the space used and the accuracy of approximation. We also
present space-efficient algorithms for estimating the number of butterflies
within a sliding window of the most recent elements in the stream. While there
is a significant body of work on counting subgraphs such as triangles in a
unipartite graph stream, our work seems to be one of the few to tackle the case
of bipartite graph streams.Comment: This is the author's version of the work. It is posted here by
permission of ACM for your personal use. Not for redistribution. The
definitive version was published in Seyed-Vahid Sanei-Mehri, Yu Zhang, Ahmet
Erdem Sariyuce and Srikanta Tirthapura. "FLEET: Butterfly Estimation from a
Bipartite Graph Stream". The 28th ACM International Conference on Information
and Knowledge Managemen
Disorder-Induced Multiple Transition involving Z2 Topological Insulator
Effects of disorder on two-dimensional Z2 topological insulator are studied
numerically by the transfer matrix method. Based on the scaling analysis, the
phase diagram is derived for a model of HgTe quantum well as a function of
disorder strength and magnitude of the energy gap. In the presence of sz
non-conserving spin-orbit coupling, a finite metallic region is found that
partitions the two topologically distinct insulating phases. As disorder
increases, a narrow-gap topologically trivial insulator undergoes a series of
transitions; first to metal, second to topological insulator, third to metal,
and finally back to trivial insulator. We show that this multiple transition is
a consequence of two disorder effects; renormalization of the band gap, and
Anderson localization. The metallic region found in the scaling analysis
corresponds roughly to the region of finite density of states at the Fermi
level evaluated in the self-consistent Born approximation.Comment: 5 pages, 5 figure
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Ability-Based Design: Concept, Principles and Examples
Current approaches to accessible computing share a common goal of making technology accessible to users with disabilities. Perhaps because of this goal, they may also share a tendency to centralize disability rather than ability. We present a refinement to these approaches called ability-based design that consists of focusing on ability throughout the design process in an effort to create systems that leverage the full range of human potential. Just as user-centered design shifted the focus of interactive system design from systems to users, ability-based design attempts to shift the focus of accessible design from disability to ability. Although prior approaches to accessible computing may consider users’ abilities to some extent, ability-based design makes ability its central focus. We offer seven ability-based design principles and describe the projects that inspired their formulation. We also present a research agenda for ability-based design.Engineering and Applied Science
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