21,902 research outputs found
On the possibility of Vacuum-QED measurements with gravitational wave detectors
Quantum electro dynamics (QED) comprises virtual particle production and thus
gives rise to a refractive index of the vacuum larger than unity in the
presence of a magnetic field. This predicted effect has not been measured to
date, even after considerable effort of a number of experiments. It has been
proposed by other authors to possibly use gravitational wave detectors for such
vacuum QED measurements, and we give this proposal some new consideration in
this paper. In particular we look at possible source field magnet designs and
further constraints on the implementation at a gravitational wave detector. We
conclude that such an experiment seems to be feasible with permanent magnets,
yet still challenging in its implementation.Comment: 11 pages, 10 figure
Field structure and electron life times in the MEFISTO Electron Cyclotron Resonance Ion Source
The complex magnetic field of the permanent-magnet electron cyclotron
resonance (ECR) ion source MEFISTO located at the University of Bern have been
numerically simulated. For the first time the magnetized volume qualified for
electron cyclotron resonance at 2.45 GHz and 87.5 mT has been analyzed in
highly detailed 3D simulations with unprecedented resolution. New results were
obtained from the numerical simulation of 25211 electron trajectories. The
evident characteristic ion sputtering trident of hexapole confined ECR sources
has been identified with the field and electron trajectory distribution.
Furthermore, unexpected long electron trajectory lifetimes were found.Comment: 11 pages, 18 figure
Rare Earths and the Balance Problem: How to Deal with Changing Markets?
The balance between the market demand and the natural abundance of the rare-earth elements (REEs) in ores, often referred to as the Balance Problem (or the Balancing Problem), is a major issue for REE suppliers. The ideal situation is a perfect match between the market demand for and the production of REEs, so that there are no surpluses of any of the REEs. This means that the rare-earth industry must find new uses for REEs that are available in excess and search for substitutes for REEs that have either limited availability or are high in demand. We present an overview of the trends in the applications for the different REEs and show that the demand for REEs for use in magnets, catalysts, and alloys is still increasing, while the application of REEs in polishing agents, glass, and ceramics are stable. On the other hand, the use of REEs in nickel–metal-hydride (NiMH) batteries and lamp phosphors is decreasing. These changes in the REE market have an influence on the Balance Problem, because the REEs that can be recycled from fluorescent lamps, cathode-ray tubes (CRTs), and NiMH batteries have to be at least partly reused in other applications. Magnesium and aluminum alloys offer an opportunity to mitigate the Balance Problem caused by these changes in the REE market. This is illustrated for REEs that can be recycled from fluorescent-lamp phosphor waste, CRT phosphors, and NiMH batteries. At present, five REEs (Nd, Eu, Tb, Dy, and Y) are being considered as very critical by Europe, the United States, and Japan, but we forecast that in the medium term, only neodymium will remain a critical REE. This paper discusses the relationship between criticality and the Balance Problem and shows how this relationship influences the market for specific REEs.This work has received funding from the European Union’s Horizon 2020 research and innovation programme under Grant Agreement No 680629 (REMAGHIC: New Recovery Processes to produce Rare Earth-Magnesium Alloys of High Performance and Low Cost) (project website: http://www.remaghic-project. eu). KB and PTJ acknowledge funding from the European Community’s Seventh Framework Programme ([FP7/2007–2013]) under Grant Agreement No. 607411 (MC-ITN EREAN: European Rare Earth Magnet Recycling Network) (project website of EREAN: http:// www.erean.eu). Paul McGuiness (Sciencewriter.si, Slovenia) is acknowledged for the drawing of the figures
A Zeeman Slower based on magnetic dipoles
A transverse Zeeman slower composed of an array of compact discrete neodymium
magnets is considered. A simple and precise model of such a slower based on
magnetic dipoles is developed. The theory of a general Zeeman slower is
modified to include spatial nonuniformity of the slowing laser beam intensity
due to its convergence and absorption by slowed atoms. The slower needs no high
currents or water cooling and the spatial distribution of its magnetic field
can be adjusted. In addition the slower provides a possibility to cool the
slowed atoms transversally along the whole length of the slower. Such a slower
would be ideal for transportable optical atomic clocks and their future
applications in space physics.Comment: 17 pages, 9 figure
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