9,987 research outputs found
Optimizing the performance of thermionic devices using energy filtering
Conventional thermionic power generators and refrigerators utilize a barrier
in the direction of transport to selectively transmit high-energy electrons.
Here we show that the energy spectrum of electrons transmitted in this way is
not optimal, and we derive the ideal energy spectrum for operation in the
maximum power regime. By using suitable energy filters, such as resonances in
quantum dots, the power of thermionic devices can, in principle, be improved by
an order of magnitude.Comment: 3 pages, 2 figure
Performance of the Cell processor for biomolecular simulations
The new Cell processor represents a turning point for computing intensive
applications. Here, I show that for molecular dynamics it is possible to reach
an impressive sustained performance in excess of 30 Gflops with a peak of 45
Gflops for the non-bonded force calculations, over one order of magnitude
faster than a single core standard processor
Modulated voltage metastable ionization detector
The output current from a metastable ionization detector (MID) is applied to a modulation voltage circuit. An adjustment is made to balance out the background current, and an output current, above background, is applied to an input of a strip chart recorder. For low level concentrations, i.e., low detected output current, the ionization potential will be at a maximum and the metastable ionization detector will operate at its most sensitive level. When the detected current from the metastable ionization detector increases above a predetermined threshold level, a voltage control circuit is activated which turns on a high voltage transistor which acts to reduce the ionization potential. The ionization potential applied to the metastable ionization detector is then varied so as to maintain the detected signal level constant. The variation in ionization potential is now related to the concentration of the constituent and a representative amplitude is applied to another input of said strip chart recorder
Radiating Bondi and Cooling Site Flows
Steady accretion of a radiating gas onto a central mass point is described
and compared to classic Bondi accretion. Radiation losses are essential for
accretion flows to be observed. Unlike Bondi flows, radiating Bondi flows pass
through a sonic point at a finite radius and become supersonic near the center.
The morphology of all radiating Bondi flows is described by a single
dimensionless parameter. In radiating Bondi flows the mass accretion rate
varies approximately as the first power of the central mass -- this differs
significantly from the quadratic dependence on the central mass in classical
Bondi flows. Mass accretion rates onto galaxy or cluster-centered black holes
estimated from traditional and radiating Bondi flows are significantly
different. In radiating Bondi flows the gas temperature increases at large
radii, as in the cores of many galaxy groups and clusters, allowing radiating
Bondi flows to merge naturally with gas arriving from their cluster
environments. Some radiating flows cool completely before reaching the center
of the flow, and this also occurs in cooling site flows in which there is no
central gravitating mass.Comment: 9 pages with 3 figures; accepted by Ap
Enhancing Science Instruction through the use of Graphic Organizers
Just as a secondary social studies class requires students to meet a demanding curriculum and have a good deal of background knowledge, so does a secondary science class. Since research supports the use of graphic organizers, the purpose of this study is to investigate the impact of graphic organizers on content–area learning for high school students in a resource room for biology class where the teacher uses effective teaching practices. The study will specifically focus on improving science vocabulary, comprehension, and storing and recalling information by enhancing science instruction
Hydrostatic Gas Constraints On Supermassive Black Hole Masses: Implications For Hydrostatic Equilibrium And Dynamical Modeling In A Sample Of Early-Type Galaxies
We present new mass measurements for the supermassive black holes (SMBHs) in the centers of three early-type galaxies. The gas pressure in the surrounding, hot interstellar medium (ISM) is measured through spatially resolved spectroscopy with the Chandra X-ray Observatory, allowing the SMBH mass (M(BH)) to be inferred directly under the hydrostatic approximation. This technique does not require calibration against other SMBH measurement methods and its accuracy depends only on the ISM being close to hydrostatic, which is supported by the smooth X-ray isophotes of the galaxies. Combined with results from our recent study of the elliptical galaxy NGC4649, this brings the number of galaxies with SMBHs measured in this way to four. Of these, three already have mass determinations from the kinematics of either the stars or a central gas disk, and hence join only a handful of galaxies with MBH measured by more than one technique. We find good agreement between the different methods, providing support for the assumptions implicit in both the hydrostatic and the dynamical models. The stellar mass-to-light ratios for each galaxy inferred by our technique are in agreement with the predictions of stellar population synthesis models assuming a Kroupa initial mass function (IMF). This concurrence implies that no more than similar to 10%-20% of the ISM pressure is nonthermal, unless there is a conspiracy between the shape of the IMF and nonthermal pressure. Finally, we compute Bondi accretion rates (M(bondi)), finding that the two galaxies with the highest M(bondi) exhibit little evidence of X-ray cavities, suggesting that the correlation with the active galactic nuclei jet power takes time to be established.NASA NAS5-26555, NNG04GE76G, G07-8083XAstronom
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