4,974 research outputs found
Development of computational fluid dynamics at NASA Ames Research Center
Ames Research Center has the lead role among NASA centers to conduct research in computational fluid dynamics. The past, the present, and the future prospects in this field are reviewed. Past accomplishments include pioneering computer simulations of fluid dynamics problems that have made computers valuable in complementing wind tunnels for aerodynamic research. The present facilities include the most powerful computers built in the United States. Three examples of viscous flow simulations are presented: an afterbody with an exhaust plume, a blunt fin mounted on a flat plate, and the Space Shuttle. The future prospects include implementation of the Numerical Aerodynamic Simulation Processing System that will provide the capability for solving the viscous flow field around an aircraft in a matter of minutes
Simulation Applications at NASA Ames Research Center
Aeronautical applications of simulation technology at Ames Research Center are described. The largest wind tunnel in the world is used to determine the flow field and aerodynamic characteristics of various aircraft, helicopter, and missile configurations. Large computers are used to obtain similar results through numerical solutions of the governing equations. Capabilities are illustrated by computer simulations of turbulence, aileron buzz, and an exhaust jet. Flight simulators are used to assess the handling qualities of advanced aircraft, particularly during takeoff and landing
Numerical solutions for blunt axisymmetric bodies in a supersonic spherical source flow
Numerical solutions for blunt axisymmetric bodies in supersonic spherical source flo
Dimensional instability of aluminum alloys for extreme low temperature cycling applications /GGV material instability problem/
Dimensional instability of aluminum alloys during cryogenic thermal cyclin
Shock shapes and pressure distributions for large angle pointed cones in helium at Mach numbers of 8 and 20
Shock shape and surface pressure measurements on hypersonic pointed cones in heliu
Quantum effects in the collective light scattering by coherent atomic recoil in a Bose-Einstein condensate
We extend the semiclassical model of the collective atomic recoil laser
(CARL) to include the quantum mechanical description of the center-of-mass
motion of the atoms in a Bose-Einstein condensate (BEC). We show that when the
average atomic momentum is less than the recoil momentum , the
CARL equations reduce to the Maxwell-Bloch equations for two momentum levels.
In the conservative regime (no radiation losses), the quantum model depends on
a single collective parameter, , that can be interpreted as the average
number of photons scattered per atom in the classical limit. When ,
the semiclassical CARL regime is recovered, with many momentum levels populated
at saturation. On the contrary, when , the average momentum
oscillates between zero and , and a periodic train of
hyperbolic secant pulses is emitted. In the dissipative regime (large radiation
losses) and in a suitable quantum limit, a sequential superfluorescence
scattering occurs, in which after each process atoms emit a hyperbolic
secant pulse and populate a lower momentum state. These results describe the
regular arrangement of the momentum pattern observed in recent experiments of
superradiant Rayleigh scattering from a BEC.Comment: submitted for publication on Phys. Rev.
Does matter wave amplification work for fermions?
We discuss the relationship between bosonic stimulation, density
fluctuations, and matter wave gratings. It is shown that enhanced stimulated
scattering, matter wave amplification and atomic four-wave mixing are in
principle possible for fermionic or non-degenerate samples if they are prepared
in a cooperative state. In practice, there are limitations by short coherence
times.Comment: 5 pages, 1 figure
Surge current and electron swarm tunnel tests of thermal blanket and ground strap materials
The results are described of a series of current conduction tests with a thermal control blanket to which grounding straps have been attached. The material and the ground strap attachment procedure are described. The current conduction tests consisted of a surge current examination of the ground strap and a dilute flow, energetic electron deposition and transport through the bulk of the insulating film of this thermal blanket material. Both of these test procedures were used previously with thermal control blanket materials
Hoʻolohe Pono: Listening to the Voices of Parents and Community to Envision a School-Family-Community Partnership at Waimānalo School
D.Ed.D.Ed. Thesis. University of Hawaiʻi at Mānoa 201
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