24,474 research outputs found
Quantum Key Distribution by Utilizing Four-Level Particles
We present a quantum key distribution protocol based on four-level particles
entanglement. Furthermore, a controlled quantum key distribution protocol is
proposed by utilizing three four-level particles. We show that the two
protocols are secure.Comment: 5 pages, no figur
Asteroseismic Study on Cluster Distance Moduli for RGB Stars in NGC 6791 and NGC 6819
Stellar distance is an important basic parameter in stellar astrophysics.
Stars in a cluster are thought to be formed coevally from the same interstellar
cloud of gas and dust. They are therefore expected to have common properties.
These common properties strengthen our ability to constrain theoretical models
and/or to determine fundamental parameters, such as stellar mass, metal
fraction, and distance when tested against an ensemble of cluster stars. Here
we derive a new relation based on solar-like oscillations, photometric
observations, and the theory of stellar structure and evolution of red giant
branch stars to determine cluster distance moduli through the global
oscillation parameters and , and photometric data
\textit{V}. The values of and are derived from
\textit{kepler} observations. At the same time, it is used to interpret the
trends between \textit{V} and . From the analyses of this newly
derived relation and observational data of NGC 6791 and NGC 6819 we devise a
method in which all stars in a cluster are regarded as one entity to determine
the cluster distance modulus. This approach fully reflects the characteristic
of member stars in a cluster as a natural sample. From this method we derive
true distance moduli of mag for NGC 6791 and mag
for NGC 6819. Additionally, we find that the distance modulus only slightly
depends on the metallicity [Fe/H] in the new relation. A change of 0.1 dex in
[Fe/H] will lead to a change of 0.06 mag in the distance modulus.Comment: 9 pages, 6 figures, 4 tables, accepted Ap
Plastic Deformation Investigation Of High Energy Input Friction
In this dissertation, plastic deformation of friction surfaces under high energy input is investigated. The plastic deformation of the friction surface and subsurface was studied and models were established to estimate deformation.
In order to calculate the plastic deformation at friction surface, an algorithm based on Ramberg-Osgood relationship was generated, and a single material model was developed based on this algorithm. Work hardening caused by plastic deformation and thermal softening caused by elevated temperature were considered in the model. To validate the model, an apparatus was designed to perform friction tests under different conditions. A special steel specimen with a copper insert was prepared. A single material model was validated by the test results.
Friction materials are the composites of matrix materials, reinforcement particles, abrasive particles and lubricants. Effects of additives on plastic deformation are different. Single additive particle models were built based on the single material model
to study the effect of additives on the plastic deformation of the matrix material. The most common additives, graphite and silicon were investigated. Specimen with a single additive particle were fabricated and tested. The single additive particle models were compared to experiment results. Simulation models for more complicated
situations were discussed.
The research in this dissertation provides a mechanism to study complex friction materials, and provides a new method for friction material study. The models are convenient tools that could be used to study the friction mechanisms and improve the performance of friction material
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