1,335 research outputs found
Determination of complex absorbing potentials from the electron self-energy
The electronic conductance of a molecule making contact to electrodes is
determined by the coupling of discrete molecular states to the continuum
electrode density of states. Interactions between bound states and continua can
be modeled exactly by using the (energy-dependent) self-energy, or
approximately by using a complex potential. We discuss the relation between the
two approaches and give a prescription for using the self-energy to construct
an energy-independent, non-local, complex potential. We apply our scheme to
studying single-electron transmission in an atomic chain, obtaining excellent
agreement with the exact result. Our approach allows us to treat
electron-reservoir couplings independent of single electron energies, allowing
for the definition of a one-body operator suitable for inclusion into
correlated electron transport calculations.Comment: 11 pages, 8 figures; to be published in the J. Chem. Phy
Phase Transitions in a Dusty Plasma with Two Distinct Particle Sizes
In semiconductor manufacturing, contamination due to particulates
significantly decreases the yield and quality of device fabrication, therefore
increasing the cost of production. Dust particle clouds can be found in almost
all plasma processing environments including both plasma etching devices and in
plasma deposition processes. Dust particles suspended within such plasmas will
acquire an electric charge from collisions with free electrons in the plasma.
If the ratio of inter-particle potential energy to the average kinetic energy
is sufficient, the particles will form either a liquid structure with short
range ordering or a crystalline structure with long range ordering. Otherwise,
the dust particle system will remain in a gaseous state. Many experiments have
been conducted over the past decade on such colloidal plasmas to discover the
character of the systems formed, but more work is needed to fully understand
these structures. The preponderance of previous experiments used monodisperse
spheres to form complex plasma systems
A comparison of human brain dissection by drill versus saw on nucleic acid quality
This study examined the effect of two dissection techniques on the quality of human brain specimens. Frozen cerebellar samples were obtained from postmortem brains of 10 subjects free from neurological and psychiatric disease. These tissues were tested for RNA and DNA concentration and quality after being dissected with either an electric dental drill or a small handsaw. RNA and DNA were extracted separately from each sample, and the concentrations and quality of each were measured. We found that dissection technique does not significantly affect RNA or DNA quality/yield. RNA and DNA yields, as well as RNA integrity showed no significant differences between the two dissection techniques. Therefore, these results support the use of a high-speed hand-held electric dental drill as an efficient and anatomically precise means of human brain dissection without compromising tissue quality. Published by Elsevier B.V
The necessary future of chiropractic education: a North American perspective
The chiropractic educational system in North America is currently in a state of flux. The attempted conversion of some chiropractic schools into "universities" and the want of university affiliation for chiropractic schools suggests that we are searching for a better alternative to the present system. In the early 20(th )century, the Flexner Report helped transform modern medical education into a discipline that relies on scientific and clinical knowledge. Some have wondered if it is time for a Flexner-type report regarding the education of doctors of chiropractic. This article outlines the current challenges within the chiropractic educational system and proposes positive changes for that system
Dusty Plasma Correlation Function Experiment
Dust particles immersed within a plasma environment, such as those in
protostellar clouds, planetary rings or cometary environments, will acquire an
electric charge. If the ratio of the inter-particle potential energy to the
average kinetic energy is high enough the particles will form either a "liquid"
structure with short-range ordering or a crystalline structure with long range
ordering. Many experiments have been conducted over the past several years on
such colloidal plasmas to discover the nature of the crystals formed, but more
work is needed to fully understand these complex colloidal systems. Most
previous experiments have employed monodisperse spheres to form Coulomb
crystals. However, in nature (as well as in most plasma processing
environments) the distribution of particle sizes is more randomized and
disperse. This paper reports experiments which were carried out in a GEC rf
reference cell modified for use as a dusty plasma system, using varying sizes
of particles to determine the manner in which the correlation function depends
upon the overall dust grain size distribution. (The correlation function
determines the overall crystalline structure of the lattice.) Two dimensional
plasma crystals were formed of assorted glass spheres with specific size
distributions in an argon plasma. Using various optical techniques, the pair
correlation function was determined and compared to those calculated
numerically.Comment: 6 pages, Presented at COSPAR '0
The inner structure of very massive elliptical galaxies: implications for the inside-out formation mechanism of z~2 galaxies
We analyze a sample of 23 supermassive elliptical galaxies (central velocity
dispersion larger than 330 km s-1), drawn from the SDSS. For each object, we
estimate the dynamical mass from the light profile and central velocity
dispersion, and compare it with the stellar mass derived from stellar
population models. We show that these galaxies are dominated by luminous matter
within the radius for which the velocity dispersion is measured. We find that
the sizes and stellar masses are tightly correlated, with Re ~ M*^{1.1}$,
making the mean density within the de Vaucouleurs radius a steeply declining
function of M*: rho_e ~ M*^{-2.2}. These scalings are easily derived from the
virial theorem if one recalls that this sample has essentially fixed (but
large) sigma_0. In contrast, the mean density within 1 kpc is almost
independent of M*, at a value that is in good agreement with recent studies of
z ~ 2 galaxies. The fact that the mass within 1 kpc has remained approximately
unchanged suggests assembly histories that were dominated by minor mergers --
but we discuss why this is not the unique way to achieve this. Moreover, the
total stellar mass of the objects in our sample is typically a factor of ~ 5
larger than that in the high redshift (z ~ 2) sample, an amount which seems
difficult to achieve. If our galaxies are the evolved objects of the recent
high redshift studies, then we suggest that major mergers were required at z >
1.5, and that minor mergers become the dominant growth mechanism for massive
galaxies at z < 1.5.Comment: 11 pages, 8 figures, accepted in MNRA
Galaxy luminosities, stellar masses, sizes, velocity dispersions as a function of morphological type
We provide fits to the distribution of galaxy luminosity, size, velocity
dispersion and stellar mass as a function of concentration index C_r and
morphological type in the SDSS. We also quantify how estimates of the fraction
of `early' or `late' type galaxies depend on whether the samples were cut in
color, concentration or light profile shape, and compare with similar estimates
based on morphology. Our fits show that Es account for about 20% of the r-band
luminosity density, rho_Lr, and 25% of the stellar mass density, rho_*;
including S0s and Sas increases these numbers to 33% and 40%, and 50% and 60%,
respectively. Summed over all galaxy types, we find rho_* ~ 3 * 10^8 M_Sun
Mpc^{-3} at z ~ 0. This is in good agreement with expectations based on
integrating the star formation history. However, compared to most previous
work, we find an excess of objects at large masses, up to a factor of ~ 10 at
M_* ~ 5*10^{11} M_Sun. The stellar mass density further increases at large
masses if we assume different IMFs for Es and spiral galaxies, as suggested by
some recent chemical evolution models, and results in a better agreement with
the dynamical mass function. We also show that the trend for ellipticity to
decrease with luminosity is primarily because the E/S0 ratio increases at large
L. However, the most massive galaxies, M_* > 5 * 10^{11} M_Sun, are less
concentrated and not as round as expected if one extrapolates from lower L, and
they are not well-fit by pure deVaucouleur laws. This suggests formation
histories with recent radial mergers. Finally, we show that the age-size
relation is flat for Es of fixed dynamical mass, but, at fixed M_dyn, S0s and
Sas with large sizes tend to be younger. Explaining this difference between E
and S0 formation is a new challenge for models of early-type galaxy formation.Comment: 42 pages, 34 figures, 9 tables. Accepted for publication in MNRA
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