1,650 research outputs found
A public relations approach to recruiting studio audiences for start-up shows
This thesis sought to determine the methods audience coordinators used to recruit studio audiences. This portion of the thesis included a ten-question interview emailed to audience coordinators for current daytime talk shows in New York City. Interviews were also conducted with production executives and a director to determine the purpose and significance of audience as well as audience-related costs.
Second, the thesis sought to answer what audiences like and dislike, what they have done, what they will do, and what they believe as it pertains to studio attendance. This portion of the thesis included a fifteen-question survey addressing incentives, show topics, and confirmations to name a few.
The audience coordinators\u27 recruitment tactics addressed in the interviews were compared with the tactics ratings found in the survey. The results of the surveys, interviews, and review of related material indicated that many of these tactics are ineffective and financially and socially damaging to a show. Therefore, it is necessary for audience coordinators to not only re-evaluate their current recruitment practices, but their perception of what audience coordination entails
Novel Modifications of Parallel Jacobi Algorithms
We describe two main classes of one-sided trigonometric and hyperbolic
Jacobi-type algorithms for computing eigenvalues and eigenvectors of Hermitian
matrices. These types of algorithms exhibit significant advantages over many
other eigenvalue algorithms. If the matrices permit, both types of algorithms
compute the eigenvalues and eigenvectors with high relative accuracy.
We present novel parallelization techniques for both trigonometric and
hyperbolic classes of algorithms, as well as some new ideas on how pivoting in
each cycle of the algorithm can improve the speed of the parallel one-sided
algorithms. These parallelization approaches are applicable to both
distributed-memory and shared-memory machines.
The numerical testing performed indicates that the hyperbolic algorithms may
be superior to the trigonometric ones, although, in theory, the latter seem
more natural.Comment: Accepted for publication in Numerical Algorithm
Graphene: Status and Prospects
Graphene is a wonder material with many superlatives to its name. It is the
thinnest material in the universe and the strongest ever measured. Its charge
carriers exhibit giant intrinsic mobility, have the smallest effective mass (it
is zero) and can travel micrometer-long distances without scattering at room
temperature. Graphene can sustain current densities 6 orders higher than
copper, shows record thermal conductivity and stiffness, is impermeable to
gases and reconciles such conflicting qualities as brittleness and ductility.
Electron transport in graphene is described by a Dirac-like equation, which
allows the investigation of relativistic quantum phenomena in a bench-top
experiment. What are other surprises that graphene keeps in store for us? This
review analyses recent trends in graphene research and applications, and
attempts to identify future directions in which the field is likely to develop.Comment: pre-edited version of the review published in Science Please note
that only 40 references are allowed by the magazine. Sorr
Monolayer MoS2 strained to 1.3% with a microelectromechanical system
We report on a modified transfer technique for atomically thin materials integrated onto microelectromechanical
systems (MEMS) for studying strain physics and creating strain-based devices. Our method tolerates the non-planar
structures and fragility of MEMS, while still providing precise positioning and crack free transfer of flakes. Further,
our method used the transfer polymer to anchor the 2D crystal to the MEMS, which reduces the fabrication time,
increases the yield, and allowed us to exploit the strong mechanical coupling between 2D crystal and polymer to
strain the atomically thin system. We successfully strained single atomic layers of molybdenum disulfide (MoS2) with
MEMS devices for the first time and achieved greater than 1.3% strain, marking a major milestone for incorporating
2D materials with MEMS We used the established strain response of MoS2 Raman and Photoluminescence spectra to
deduce the strain in our crystals and provide a consistency check. We found good comparison between our experiment
and literature.Published versio
Universal Dynamic Conductivity and Quantized Visible Opacity of Suspended Graphene
We show that the optical transparency of suspended graphene is defined by the
fine structure constant, alpha, the parameter that describes coupling between
light and relativistic electrons and is traditionally associated with quantum
electrodynamics rather than condensed matter physics. Despite being only one
atom thick, graphene is found to absorb a significant (pi times alpha=2.3%)
fraction of incident white light, which is a consequence of graphene's unique
electronic structure. This value translates into universal dynamic conductivity
G =e^2/4h_bar within a few percent accuracy
Apollo 15 rake sample microbreccias and non-mare rocks: Bulk rock, mineral and glass electron microprobe analyses
Quantitative electron microprobe data of Apollo 15 nonmare rake samples are presented. Bulk analyses of lithic fragments in the nomare rocks (expressed in oxide weight-percent) and the corresponding CIPW molecular norms are given. The mineralogy of the rocks and lithic fragments are also given; structural formulae for complete analyses and molecular end-members for all mineral analyses are included. The mineral analyses include pyroxene, olivine, plagioclase, barian K-feldspar, spinel and ilmenite, cobaltian metallic nickel-iron as well as SiO2-K2O-rich residual glass. Electron micropobe analyses (oxide weight percent) of glasses in loose fines and microbreccia samples and their CIPW molecular norms are presented along with electron microprobe data on bulk, mineral, and matrix glass from chondrules
Energy-Momentum Tensor of Particles Created in an Expanding Universe
We present a general formulation of the time-dependent initial value problem
for a quantum scalar field of arbitrary mass and curvature coupling in a FRW
cosmological model. We introduce an adiabatic number basis which has the virtue
that the divergent parts of the quantum expectation value of the
energy-momentum tensor are isolated in the vacuum piece of , and
may be removed using adiabatic subtraction. The resulting renormalized
is conserved, independent of the cutoff, and has a physically transparent,
quasiclassical form in terms of the average number of created adiabatic
`particles'. By analyzing the evolution of the adiabatic particle number in de
Sitter spacetime we exhibit the time structure of the particle creation
process, which can be understood in terms of the time at which different
momentum scales enter the horizon. A numerical scheme to compute as a
function of time with arbitrary adiabatic initial states (not necessarily de
Sitter invariant) is described. For minimally coupled, massless fields, at late
times the renormalized goes asymptotically to the de Sitter invariant
state previously found by Allen and Folacci, and not to the zero mass limit of
the Bunch-Davies vacuum. If the mass m and the curvature coupling xi differ
from zero, but satisfy m^2+xi R=0, the energy density and pressure of the
scalar field grow linearly in cosmic time demonstrating that, at least in this
case, backreaction effects become significant and cannot be neglected in de
Sitter spacetime.Comment: 28 pages, Revtex, 11 embedded .ps figure
Band Gap Engineering with Ultralarge Biaxial Strains in Suspended Monolayer MoS2
We demonstrate the continuous and reversible tuning of the optical band gap
of suspended monolayer MoS2 membranes by as much as 500 meV by applying very
large biaxial strains. By using chemical vapor deposition (CVD) to grow
crystals that are highly impermeable to gas, we are able to apply a pressure
difference across suspended membranes to induce biaxial strains. We observe the
effect of strain on the energy and intensity of the peaks in the
photoluminescence (PL) spectrum, and find a linear tuning rate of the optical
band gap of 99 meV/%. This method is then used to study the PL spectra of
bilayer and trilayer devices under strain, and to find the shift rates and
Gr\"uneisen parameters of two Raman modes in monolayer MoS2. Finally, we use
this result to show that we can apply biaxial strains as large as 5.6% across
micron sized areas, and report evidence for the strain tuning of higher level
optical transitions.Comment: Nano Lett., Article ASA
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