344 research outputs found
A Matrix Model of Argumentation
This paper presents a two-dimensional teaching model of argumentation that evolved over a number of years. It was originally developed out of Stephen Toulmin’s model and offers a ‘matrix approach’ to the analysis of complex rhetorical events. The two dimensions of the matrix involve the analysis of the sub-claims used to support the ultimate claim in a rhetorical artifact and the way in which those sub-claims are organized. This paper briefly presents the background, rationale, basic elements, and structure of the model. And while there is insufficient space to provide a full, detailed example, this paper will suggest some illustrative applications
Lunar sample analysis
The surface composition of two samples from the highly shocked, glass-coated lunar basalt (12054) and from four glass-coated fragments from the 1-2 mm (14161) fines were examined by X-ray photoemission spectroscopy to determine whether the agglutination process itself is responsible for the difference between their surface and bulk compositions. Auger electron spectroscopy of glass balls from the 15425 and 74001 fines were analyzed to understand the nature, extent, and behavior of volatile phases associated with lunar volcanism. Initial results indicate that (1) volatiles, in the outer few atomic layers sampled, vary considerably from ball to ball; (2) variability over the surface of individual balls is smaller; (3) the dominant volatiles on the balls are S and Zn; and (4) other volatiles commonly observed are P, Cl, and K
Lunar sample analysis
Results are presented from an extensive series of new high resolution scanning electron microscope studies of the very primative group of meteorites known as unequilibrated chondrites. These include quantitative analyses of micrometer sized phases and interpretation in terms of relevant phase equilibria. Several new meteorite minerals including high chromium metal, have been discovered
Nanowire quantum dots tuned to atomic resonances
Quantum dots tuned to atomic resonances represent an emerging field of hybrid
quantum systems where the advantages of quantum dots and natural atoms can be
combined. Embedding quantum dots in nanowires boosts these systems with a set
of powerful possibilities, such as precise positioning of the emitters,
excellent photon extraction efficiency and direct electrical contacting of
quantum dots. Notably, nanowire structures can be grown on silicon substrates,
allowing for a straightforward integration with silicon-based photonic devices.
In this work we show controlled growth of nanowire-quantum-dot structures on
silicon, frequency tuned to atomic transitions. We grow GaAs quantum dots in
AlGaAs nanowires with a nearly pure crystal structure and excellent optical
properties. We precisely control the dimensions of quantum dots and their
position inside nanowires, and demonstrate that the emission wavelength can be
engineered over the range of at least around . By applying an
external magnetic field we are able to fine tune the emission frequency of our
nanowire quantum dots to the transition of Rb. We use the Rb
transitions to precisely measure the actual spectral linewidth of the photons
emitted from a nanowire quantum dot to be , under
non-resonant excitation. Our work brings highly-desirable functionalities to
quantum technologies, enabling, for instance, a realization of a quantum
network, based on an arbitrary number of nanowire single-photon sources, all
operating at the same frequency of an atomic transition.Comment: main text (20 pages, 3 figures) plus supplementary information, Nano
Letters (2018
Ferromagnetic (Ga,Mn)As nanowires grown by Mn-assisted molecular beam epitaxy
(Ga,Mn)As nanowires were grown by molecular beam epitaxy using Mn as a growth catalyst on GaAs(001) substrates at 485 °C, i.e., at intermediate temperatures higher than ones used for the growth of (Ga,Mn)As thin films, but lower than the ordinary temperatures of Au-assisted growth of GaAs nanowires. (Ga,Mn)As nanowires obtained with typical lengths between 0.8 and 4 μm and diameters 50–90 nm do not have defects, such as dislocations or precipitates, except for the stacking faults lying parallel to the growth direction. The investigation of magnetic and optical properties has been carried out not only for as-grown samples with nanowires but also for peeled off nanowires from the host substrate. The results obtained demonstrate that (Ga,Mn)As nanowires exhibit ferromagnetic ordering around 70 K.Peer reviewe
Super-resolution provided by the arbitrarily strong superlinearity of the blackbody radiation
Blackbody radiation is a fundamental phenomenon in nature, and its explanation by Planck marks a cornerstone in the history of Physics. In this theoretical work, we show that the spectral radiance given by Planck's law is strongly superlinear with temperature, with an arbitrarily large local exponent for decreasing wavelengths. From that scaling analysis, we propose a new concept of super-resolved detection and imaging: if a focused beam of energy is scanned over an object that absorbs and linearly converts that energy into heat, a highly nonlinear thermal radiation response is generated, and its point spread function can be made arbitrarily smaller than the excitation beam focus. Based on a few practical scenarios, we propose to extend the notion of super-resolution beyond its current niche in microscopy to various kinds of excitation beams, a wide range of spatial scales, and a broader diversity of target objects
Does the thermal spike affect low-energy ion-induced interfacial mixing?
Molecular dynamics simulations have been used to obtain the three-dimensional
distribution of interfacial mixing and cascade defects in Ti/Pt multilayer
system due to single 1 keV impacts at grazing angle of incidence. The
Ti/Pt system was chosen because of its relatively high heat of mixing in the
binary alloy and therefore a suitable candidate for testing the effect of heat
of mixing on ion-beam mixing. However, the calculated mixing profile is not
sensitive to the heat of mixing. Therefore the thermal spike model of mixing is
not fully supported under these irradiation conditions. Instead we found that
the majority of mixing occurs after the thermal spike during the relaxation
process. These conclusions are supported by liquid, vacancy as well as adatom
analysis. The interfacial mixing is in various aspects anomalous in this
system: the time evolution of mixing is leading to a phase delay for Ti mixing,
and Pt exhibits an unexpected double peaked mixing evolution. The reasons to
these effects are discussed.Comment: 7 pages, 12 figures, Nucl. Instr. Meth. B211, 524. (2003
Optical Study of GaAs quantum dots embedded into AlGaAs nanowires
We report on the photoluminescence characterization of GaAs quantum dots
embedded into AlGaAs nano-wires. Time integrated and time resolved
photoluminescence measurements from both an array and a single quantum
dot/nano-wire are reported. The influence of the diameter sizes distribution is
evidenced in the optical spectroscopy data together with the presence of
various crystalline phases in the AlGaAs nanowires.Comment: 5 page, 5 figure
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