3,700 research outputs found
Direct Optical Coupling to an Unoccupied Dirac Surface State in the Topological Insulator BiSe
We characterize the occupied and unoccupied electronic structure of the
topological insulator BiSe by one-photon and two-photon angle-resolved
photoemission spectroscopy and slab band structure calculations. We reveal a
second, unoccupied Dirac surface state with similar electronic structure and
physical origin to the well-known topological surface state. This state is
energetically located 1.5 eV above the conduction band, which permits it to be
directly excited by the output of a Ti:Sapphire laser. This discovery
demonstrates the feasibility of direct ultrafast optical coupling to a
topologically protected, spin-textured surface state.Comment: Accepted to Physical Review Letter
Master of Science
thesisThe High Altitude Ice Crystals - High Ice Water Content (HAIC-HIWC) field campaign produced aircraft retrievals of total condensed water content (TWC), hydrometeor particle size distributions, and vertical velocity (w) in high ice water content regions of tropical mesoscale convective systems (MCSs). These observations are used to evaluate deep convective updraft properties in high-resolution nested Weather Research and Forecasting (WRF) simulations of observed MCSs. Because simulated hydrometeor properties are highly sensitive to the parameterization of microphysics, three commonly used microphysical parameterizations are tested, including two bulk schemes (Thompson and Morrison) and one bin scheme (Fast Spectral Bin Microphysics). A commonly documented bias in cloud-resolving simulations is the exaggeration of simulated radar reflectivities aloft in tropical MCSs. This may result from overly strong convective updrafts that loft excessive condensate mass and from simplified approximations of hydrometeor size distributions, properties, species separation, and microphysical processes. The degree to which the reflectivity bias is a separate function of convective dynamics, condensate mass, and hydrometeor size has yet to be addressed. This research untangles these components by comparing simulated and observed relationships between w, TWC, and hydrometer size as a function of temperature. All microphysics schemes produce median mass diameters that are generally larger than observed for temperatures between -10 °C and -40 °C and TWC > 1 g m-3. Observations produce a prominent mode in the composite mass size distribution around 300 µm, but under most conditions, all schemes shift the distribution mode to larger sizes. Despite a much greater number of samples, all simulations fail to reproduce observed high TWC or high w conditions between -20 °C and -40 °C in which only a small fraction of condensate mass is found in relatively large particle sizes. Increasing model resolution and employing explicit cloud droplet nucleation decrease the size bias, but not nearly enough to reproduce observations. Because simulated particle sizes are too large across all schemes when controlling for temperature, w, and TWC, this bias is hypothesized to partly result from errors in parameterized microphysical processes in addition to overly simplified hydrometeor properties such as mass-size relationships and particle size distribution parameters
Origin of charge density at LaAlO3-on-SrTiO3 hetero-interfaces; possibility of intrinsic doping
As discovered by Ohtomo et al., a large sheet charge density with high
mobility exists at the interface between SrTiO3 and LaAlO3. Based on transport,
spectroscopic and oxygen-annealing experiments, we conclude that extrinsic
defects in the form of oxygen vacancies introduced by the pulsed laser
deposition process used by all researchers to date to make these samples is the
source of the large carrier densities. Annealing experiments show a limiting
carrier density. We also present a model that explains the high mobility based
on carrier redistribution due to an increased dielectric constant.Comment: 14 pages, 3 figures, 1 table; accepted for publication in Phys. Rev.
Lett
The effect of injector-element scale on the mixing and combustion of nitrogen tetroxide-hydrazine propellants
Injector-element physical size effect on mixing and combustion of nitrogen tetroxide-hydrazine propellant
The emergency observation and assessment ward
A recent development to reduce ED crowding and increase urgent patient admissions is the opening of an Emergency Observation and Assessment Ward (EOA Ward). At these wards urgent patients are temporarily hospitalized until they can be transferred to an inpatient bed. In this paper we present an overflow model to evaluate the effect of employing an EOA Ward on elective and urgent patient admissions
Overview of crew member energy expenditure during Shuttle Flight 61-8 EASE/ACCESS task performance
The energy expenditure of the Shuttle Flight 61-B crewmembers during the extravehicular performance of Experimental Assembly of Structures in EVA (EASE) and Assembly Concept of Construction of Space Structures (ACCESS) construction system tasks are reported. These data consist of metabolic rate time profiles correlated with specific EASE and ACCESS tasks and crew comments. Average extravehicular activity metabolic rates are computed and compared with those reported from previous Apollo, Shylab, and Shuttle flights. These data reflect total energy expenditure and not that of individual muscle groups such as hand and forearm. When correlated with specific EVA tasks and subtasks, the metabolic profile data is expected to be useful in planning future EVA protocols. For example, after experiencing high work rates and apparent overheating during some Gemini EVAs, it was found useful to carefully monitor work rates in subsequent flights to assess the adequacy of cooling garments and as an aid to preplanning EVA procedures. This presentation is represented by graphs and charts
A symmetry algebra in double-scaled SYK
The double-scaled limit of the Sachdev-Ye-Kitaev (SYK) model takes the number
of fermions and their interaction number to infinity in a coordinated way. In
this limit, two entangled copies of the SYK model have a bulk description of
sorts known as the "chord Hilbert space." We analyze a symmetry algebra acting
on this Hilbert space, generated by the two Hamiltonians together with a
two-sided operator known as the chord number. This algebra is a deformation of
the JT gravitational algebra, and it contains a subalgebra that is a
deformation of the near-horizon symmetries. The subalgebra
has finite-dimensional unitary representations corresponding to matter moving
around in a discrete Einstein-Rosen bridge. In a semiclassical limit the
discreteness disappears and the subalgebra simplifies to , but
with a non-standard action on the boundary time coordinate. One can make the
action of algebra more standard at the cost of extending the
boundary circle to include some "fake" portions. Such fake portions also
accommodate certain subtle states that survive the semi-classical limit,
despite oscillating on the scale of discreteness. We discuss applications of
this algebra, including sub-maximal chaos, the traversable wormhole protocol,
and a two-sided OPE.Comment: 70 page
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