5,873 research outputs found
Electron pair emission from surfaces: some general experimental considerations
We discuss some experimental facets of electron pair emission from surfaces using two different experimental approaches. In the first case the instrument consists of a pair of hemispherical analyzers which are operated with continuous primary beams of electrons or photons. The second instrument employs a pair of time-of-flight spectrometers which require a pulsed excitation source. A key experimental quantity is the ratio of ‘true’ to ‘random’ coincidences which can be determined in different ways. Regardless of the type of instrument the primary flux has to adopt a much smaller value than in single electron spectroscopy. We describe different approaches to obtain the relevant count rates, in particular the concept of operating with a delayed coincidence circuit. We also address the question on how to compare the two types of spectrometer in terms of their performance
Extended energy range analysis for angle-resolved time-of-flight photoelectron spectroscopy
An approximation method for electrostatic time-of-flight (ToF) spectroscopy on photoelectrons distributed over a wide energy range is presented. This method is an extension of conventional analysis and aims at specific energy and angular regions, where distinctly different emission angles and energies are mapped to the same ToF and detector position by the spectrometer. The general formulation and the systematic errors are presented, and a practical example is demonstrated for photoelectrons from Ag(001) with kinetic energies of 0.5–25 eV
Dynamics of the Pionium with the Density Matrix Formalism
The evolution of pionium, the hydrogen-like atom, while passing
through matter is solved within the density matrix formalism in the first Born
approximation. We compare the influence on the pionium break-up probability
between the standard probabilistic calculations and the more precise picture of
the density matrix formalism accounting for interference effects. We focus our
general result in the particular conditions of the DIRAC experiment at CERN.Comment: 14 pages, 2 figures, submitted to J. Phys. B: At. Mol. Phy
Structural and magnetic properties of an InGaAs/FeSi superlattice in cylindrical geometry
The structure and the magnetic properties of an InGaAs/Fe3Si superlattice in
a cylindrical geometry are investigated by electron microscopy techniques,
x-ray diffraction and magnetometry. To form a radial superlattice, a
pseudomorphic InGaAs/Fe3As bilayer has been released from its substrate
self-forming into a rolled-up microtube. Oxide-free interfaces as well as areas
of crystalline bonding are observed and an overall lattice mismatch between
succeeding layers is determined. The cylindrical symmetry of the final radial
superlattice shows a significant effect on the magnetization behavior of the
rolled-up layers
SOCIAL CONSTRAINTS ON ADULT LANGUAGE LEARNING
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/73181/1/j.1749-6632.1981.tb42015.x.pd
Magneto-optical trap for metastable helium at 389 nm
We have constructed a magneto-optical trap (MOT) for metastable triplet
helium atoms utilizing the 2 3S1 -> 3 3P2 line at 389 nm as the trapping and
cooling transition. The far-red-detuned MOT (detuning Delta = -41 MHz)
typically contains few times 10^7 atoms at a relatively high (~10^9 cm^-3)
density, which is a consequence of the large momentum transfer per photon at
389 nm and a small two-body loss rate coefficient (2 * 10^-10 cm^3/s < beta <
1.0 * 10^-9 cm^3/s). The two-body loss rate is more than five times smaller
than in a MOT on the commonly used 2 3S1 -> 2 3P2 line at 1083 nm. Furthermore,
we measure a temperature of 0.46(1) mK, a factor 2.5 lower as compared to the
1083 nm case. Decreasing the detuning to Delta= -9 MHz results in a cloud
temperature as low as 0.25(1) mK, at small number of trapped atoms. The 389 nm
MOT exhibits small losses due to two-photon ionization, which have been
investigated as well.Comment: 11 page
Tunneling anisotropic magnetoresistance in organic spin valves
We report the observation of tunneling anisotropic magnetoresistance (TAMR)
in an organic spin-valve-like structure with only one ferromagnetic electrode.
The device is based on a new high mobility perylene diimide-based n-type
organic semiconductor. The effect originates from the tunneling injection from
the LSMO contact and can thus occur even for organic layers which are too thick
to support the assumption of tunneling through the layer. Magnetoresistance
measurements show a clear spin-valve signal, with the typical two step
switching pattern caused by the magnetocrystalline anisotropy of the epitaxial
magnetic electrode.Comment: 10 pages 5 figures Paper has been rewritten, new results have been
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