8,573 research outputs found
Metric Perturbations and Inflationary Phase Transitions
We study the out of equilibrium dynamics of inflationary phase transitions
and compute the resulting spectrum of metric perturbations relevant to
observation. We show that simple single field models of inflation may produce
an adiabatic perturbation spectrum with a blue spectral tilt and that the
precise spectrum depends on initial conditions at the outset of inflation.Comment: 4 pages, 3 figures, COSMO-99 Proceeding
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Advances in Electron Beam Melting of Aluminum Alloys
The high thermal conductivity and melt pool optical reflectivity associated with
aluminum alloys can pose significant challenges for direct-metal SFF processes. The use
of SFF processes to produce aluminum parts is often not cost effective relative to CNC
machining for simple geometries. However, the use of SFF techniques for aluminum
alloys is justified for some applications such as aerospace forgings or high surface area
heat exchangers. This paper describes recent progress in processing aluminum alloys
using the Electron Beam Melting process. Structure and properties will be discussed, as
well challenges associated with high vapor pressure alloying elements such as zinc and
magnesium.Mechanical Engineerin
Two-Electron Effects in the Multiphoton Ionization of Magnesium with 400 nm 150 fs Pulses
The multiphoton ionization and photoelectron spectra of magnesium were
studied at laser intensities of up to 6x10^{13} Wcm^{-2} using 150 fs laser
pulses of a wavelength of 400 nm. The results indicated that a variety of
different ionization mechanisms played a role in both types of spectra. A
theoretical model describing the processes is presented and the routes to
ionization are identified. The work demonstrates the significance of the
two-electron nature of the atom in interpreting the experimental results.Comment: 14 pages, 9 figures, submitted to Physical Review
Modeling the physical properties in the ISM of the low-metallicity galaxy NGC4214
We present a model for the interstellar medium of NGC4214 with the objective
to probe the physical conditions in the two main star-forming regions and their
connection with the star formation activity of the galaxy. We used the spectral
synthesis code Cloudy to model an HII region and the associated
photodissociation region (PDR) to reproduce the emission of mid- and
far-infrared fine-structure cooling lines from the Spitzer and Herschel space
telescopes for these two regions. Input parameters of the model, such as
elemental abundances and star formation history, are guided by earlier studies
of the galaxy, and we investigated the effect of the mode in which star
formation takes place (bursty or continuous) on the line emission. Furthermore,
we tested the effect of adding pressure support with magnetic fields and
turbulence on the line predictions. We find that this model can satisfactorily
predict (within a factor of ~2) all observed lines that originate from the
ionized medium ([SIV] 10.5um, [NeIII] 15.6um, [SIII] 18.7um, [SIII] 33.5um, and
[OIII] 88um), with the exception of [NeII] 12.8um and [NII] 122um, which may
arise from a lower ionization medium. In the PDR, the [OI] 63um, [OI] 145um,
and [CII] 157um lines are matched within a factor of ~5 and work better when
weak pressure support is added to the thermal pressure or when the PDR clouds
are placed farther away from the HII regions and have covering factors lower
than unity. Our models of the HII region agree with different evolutionary
stages found in previous studies, with a more evolved, diffuse central region,
and a younger, more compact southern region. However, the local PDR conditions
are averaged out on the 175 pc scales that we probe and do not reflect
differences observed in the star formation properties of the two regions.Comment: accepted for publication in A&
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An Evaluation of Non-Stochastic Lattice Structures Fabricated Via Electron Beam Melting
Metal foam structures have many applications and can be used as structural supports, heat
exchangers, shock absorbers, and implant materials. Stochastic metal foams having different cell
sizes and densities have been commercially available for a number of years. This paper addresses
a different type of foams which are known as non-stochastic foams, or lattice structures. These
foams have a well defined repeating unit cell structure rather than the random cell structure in
commercially available stochastic foams. The paper reports on preliminary research on the
fabrication of non-stochastic Ti-6Al-4V alloy foams using the Electron Beam Melting process.
Behavior of the structures in compression, bending, and low cycle repeating load tests are
discussed, and recommendations about cell geometry and processing conditions are made.Mechanical Engineerin
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