50 research outputs found
Large Angular Momentum States in a Graphene Film
At energy lower than 2 eV, the dispersion law of the electrons in a graphene sheet presents a linear dependence of the energy on the kinetic momentum, which is typical of photons and permits the description of the electrons as massless particles by means of the Dirac equation and the study of massless particles acted upon by forces. We analytically solve the Dirac equation of an electron in a graphene disk with radius of 10,000 atomic units pierced by a magnetic field and find the eigenenergies and eigenstates of the particles for spin up and down. The magnetic field ranges within three orders of magnitude and is found to confine the electron in the disk. States with a relatively large total angular momentum exist and can be considered in a vorticose condition; these states are seen to peak at different distances from the disk centre and can be used to store few bit of information
Electrons on a spherical surface: Physical properties and hollow spherical clusters
We discuss thephysical properties of a non interacting electron gas constrained to a spherical surface. In particular we consider its chemical potentials, its ionization potential,and its electric static polarizability. All these properties are discussed analytically as functions of the number N of electrons. The trends obtained with increasing N are compared with those of the corresponding properties experimentally measured or theoretically evaluated for quasi spherical hollow atomic and molecular clusters. Most of the properties investigated display similar trends, characterized by a prominence of shell effects. This leads to the de\ufb01nition of a scale-invariant distribution of magic numbers which follows a power law with critical exponent 120.5. We conclude that our completely mechanistic and analytically tractable model can be useful for the analysis of self-assembling complex systems
Itinerant magnetic multipole moments of rank five, triakontadipoles, as the hidden order in URuSi
A broken symmetry ground state without any magnetic moments has been
calculated by means of local-density-approximation to density functional theory
plus a local exchange term, the so-called LDA+ approach, for
URuSi. The solution is analysed in terms of a multipole tensor
expansion of the itinerant density matrix and is found to be a non-trivial
magnetic multipole. Analysis and further calculations show that this type of
multipole enters naturally in time reversal breaking in presence of large
effective spin-orbit coupling and co-exists with magnetic moments for most
magnetic actinidesComment: 5 pages, 3 figure
Targeting epigenetic alterations in cancer stem cells
Oncogenes or tumor suppressor genes are rarely mutated in several pediatric
tumors and some early stage adult cancers. This suggests that an aberrant
epigenetic reprogramming may crucially affect the tumorigenesis of these
tumors. Compelling evidence support the hypothesis that cancer stem cells
(CSCs), a cell subpopulation within the tumor bulk characterized by selfrenewal
capacity, metastatic potential and chemo-resistance, may derive
from normal stem cells (NSCs) upon an epigenetic deregulation. Thus, a
better understanding of the specific epigenetic alterations driving the
transformation from NSCs into CSCs may help to identify efficacious
treatments to target this aggressive subpopulation. Moreover, deepening the
knowledge about these alterations may represent the framework to design
novel therapeutic approaches also in the field of regenerative medicine in which
bioengineering of NSCs has been evaluated. Here, we provide a broad overview
about: 1) the role of aberrant epigenetic modifications contributing to CSC
initiation, formation and maintenance, 2) the epigenetic inhibitors in clinical trial
able to specifically target the CSC subpopulation, and 3) epigenetic drugs and
stem cells used in regenerative medicine for cancer and diseases
Can we increase children’s rights endorsement and knowledge?: A pilot study based on the reference framework of competences for democratic culture
This pilot study is the first to examine whether a novel curriculum based on the Reference Framework of Competences for Democratic Culture (RFCDC) could increase children’s endorsement and knowledge of children’s rights. We conducted a pre-test-post-test design with an intervention and a comparison school. Pupils (n = 172) from Bulgaria, Italy, Norway, Romania, and Spain attended schools in which the curriculum was taught, whereas pupils in the comparison group (n = 120) attended schools in the same city where the curriculum was not taught. Both groups were tested on their endorsement and knowledge of rights before and at the end of the intervention. Children in the intervention group increased in endorsing children’s rights at post-test more than did children in the intervention group. Most children believed that children had rights. Children in the intervention group showed modest increases in their knowledge of rights. Future ways of implementing the RFCDC are suggested.publishedVersio
On the Hidden Order in URuSi --- Antiferro Hexadecapole Order and its Consequences
An antiferro ordering of an electric hexadecapole moment is discussed as a
promising candidate for the long standing mystery of the hidden order phase in
URuSi. Based on localized -electron picture, we discuss the
rationale of the selected multipole and the consequences of the antiferro
hexadecapole order of symmetry. The mean-field solutions and
the collective excitations from them explain reasonably significant
experimental observations: the strong anisotropy in the magnetic
susceptibility, characteristic behavior of pressure versus magnetic field or
temperature phase diagrams, disappearance of inelastic neutron-scattering
intensity out of the hidden order phase, and insensitiveness of the NQR
frequency at Ru-sites upon ordering. A consistency with the strong anisotropy
in the magnetic responses excludes all the multipoles in two-dimensional
representations, such as . The expected azimuthal angle
dependences of the resonant X-ray scattering amplitude are given. The
-type antiferro quadrupole should be induced by an in-plane
magnetic field along , which is reflected in the thermal expansion and
the elastic constant of the transverse mode. The
-type [-type] antiferro quadrupole is also induced by
applying the uniaxial stress along direction [ direction]. A
detection of these induced antiferro quadrupoles under the in-plane magnetic
field or the uniaxial stress using the resonant X-ray scattering provides a
direct redundant test for the proposed order parameter.Comment: 10 pages, 10 figures, 5 table
Quantum Ring in a Magnetic Field: High Harmonic Generation and NOT Logic Gate
The effect of a static magnetic field on the high harmonic generation (HHG) from a quantum ring driven by one laser polarized along the x-axis is studied. The spin polarization (Formula presented.) and the temporal emission of the harmonics are studied by varying the intensity of the magnetic field and it is shown how these results have a significant technological impact in computer technology; in fact a boolean algebra can be implemented by assigning 0 and 1 values to low and high pulse intensities of the emitted harmonics and logic gates like the NOT can be created