215 research outputs found
On the cellular autoimmune mechanism for eliminating erythrocytes normally and under extreme influences
The presence of an autoimmune cellular mechanism for destroying erythrocytes on the basis of results of experiments in vivo is demonstrated in the blood and the organs. This mechanism is made up of a population of immunocompetent killer-lymphocytes which originates in the bone marrow and the thymus, and which is manifested in the local hemolysis effect
Role of a parallel magnetic field in two dimensional disordered clusters containing a few correlated electrons
An ensemble of 2d disordered clusters with a few electrons is studied as a
function of the Coulomb energy to kinetic energy ratio r_s. Between the Fermi
system (small r_s) and the Wigner molecule (large r_s), an interaction induced
delocalization of the ground state takes place which is suppressed when the
spins are aligned by a parallel magnetic field. Our results confirm the
existence of an intermediate regime where the Wigner antiferromagnetism
defavors the Stoner ferromagnetism and where the enhancement of the Lande g
factor observed in dilute electron systems is reproduced.Comment: 4 pages, 3 figure
Strongly enhanced effective mass in dilute two-dimensional electron systems: System-independent origin
We measure the effective mass in a dilute two-dimensional electron system in
(111)-silicon by analyzing temperature dependence of the Shubnikov-de Haas
oscillations in the low-temperature limit. A strong enhancement of the
effective mass with decreasing electron density is observed. The mass
renormalization as a function of the interaction parameter r_s is in good
agreement with that reported for (100)-silicon, which shows that the relative
mass enhancement is system- and disorder-independent being determined by
electron-electron interactions only.Comment: As publishe
On stress/strain state in a rotating disk
In the framework of mechanics of continuum bodies, the problem of stress/strain state in a high-speed rotating disk of constant thickness has been considered. The material of the disk is assumed to be homogeneous, elastic/perfectly-plastic. In the plastic zone, the stresses and plastic strains are related by some associated law similar to the one employed in deformation theory of plasticity. The general algorithm of the solution covers any smooth plasticity function. At some steps of the algorithm, it is possible to get analytical expressions, particularly, for the quadratic Mises yield criterion. For the given model, the notion of control parameters (external and internal) has been introduced. The allowable boundaries of external parameters have been defined as well. For some states of the disk, the coherent values of external parameters have been obtained. The results are represented graphically to show various states of the disk. The usage of piecewise plasticity functions has been briefly discussed. The results obtained can be used in preliminary engineering design and related numerical codes.info:eu-repo/semantics/publishedVersio
Direct measurements of the fractional quantum Hall effect gaps
We measure the chemical potential jump across the fractional gap in the
low-temperature limit in the two-dimensional electron system of GaAs/AlGaAs
single heterojunctions. In the fully spin-polarized regime, the gap for filling
factor nu=1/3 increases LINEARLY with magnetic field and is coincident with
that for nu=2/3, reflecting the electron-hole symmetry in the spin-split Landau
level. In low magnetic fields, at the ground-state spin transition for nu=2/3,
a correlated behavior of the nu=1/3 and nu=2/3 gaps is observed
Microfabrication of Alkali Vapor MEMS Cells for chip-scale atomic clock
The technology of MEMS atomic cells containing rubidium or caesium vapors in an atmosphere of neon buffer gas has been developed. Two-chamber silicon cells containing an optical cavity, shallow filtration channels and a technical container for a solid-state alkali source have been implemented in a single-step process of anisotropic wet chemical etching. To prevent significant undercutting of the filtration channels during etching of the through silicon cavities, the shapes of the compensating elements at the convex corners of the silicon nitride mask have been calculated and the composition of the silicon etchant has been experimentally found. The sealing of the cells has been carried out by silicon-glass anodic bonding at a temperature of 250 оС. For this purpose the LK5 glass which has an increased ionic conductivity in comparison with the conventional glass Borofloat 33 was used. The best microfabricated cells allowed us to obtain estimates of the relative instability of the coherent population trapping resonance frequency at the level of 5·10-11 at 1 s
Sharply increasing effective mass: a precursor of the spontaneous spin polarization in a dilute two-dimensional electron system
We have measured the effective mass, m, and Lande g-factor in very dilute
two-dimensional electron systems in silicon. Two independent methods have been
used: (i) measurements of the magnetic field required to fully polarize the
electrons' spins and (ii) analysis of the Shubnikov-de Haas oscillations. We
have observed a sharp increase of the effective mass with decreasing electron
density while the g-factor remains nearly constant and close to its value in
bulk silicon. The corresponding strong rise of the spin susceptibility may be a
precursor of a spontaneous spin polarization; unlike in the Stoner scenario, it
originates from the enhancement of the effective mass rather than the increase
of g-factor. Furthermore, using tilted magnetic fields, we have found that the
enhanced effective mass is independent of the degree of spin polarization and,
therefore, its increase is not related to spin exchange effects, in
contradiction with existing theories. Our results show that the dilute 2D
electron system in silicon behaves well beyond a weakly interacting Fermi
liquid.Comment: This paper summarizes results reported in our recent publications on
the subjec
Composite fermions close to the one-half filling of the lowest Landau level revisited
By strictly adhering to the microscopic theory of composite fermions for the
Landau-level filling fractions nu_e = p/(2 p + 1), we reproduce, with
remarkable accuracy, the surface-acoustic-wave (SAW)-based experimental results
by Willett and co-workers concerning two-dimensional electron systems with nu_e
close to 1/2. Our results imply that the electron band mass m_b, as distinct
from the composite fermion mass m_*, must undergo a substantial increase under
the conditions corresponding to nu_e approximately equal to 1/2. In view of the
relatively low aerial electronic densities n_e to which the underlying SAW
experiments correspond, our finding conforms with the experimental results by
Shashkin et al. [Phys. Rev. B 66, 073303 (2002)], concerning two-dimensional
electrons in silicon, that signal sharp increase in m_b for n_e decreasing
below approximately 2 x 10^{11} cm^{-2}. We further establish that a finite
mean-free path l_0 is essential for the observed linearity of the longitudinal
conductivity sigma_{xx}(q) as deduced from the SAW velocity shifts.Comment: 5 pages, 2 postscript figure
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