Characterization of deep impurities in semiconductors by terahertz tunneling ionization

Tunneling ionization in high frequency fields as well as in static fields is suggested as a method for the characterization of deep impurities in semiconductors. It is shown that an analysis of the field and temperature dependences of the ionization probability allows to obtain defect parameters like the charge of the impurity, tunneling times, the Huang–Rhys parameter, the difference between optical and thermal binding energy, and the basic structure of the defect adiabatic potentials. Compared to static fields, high frequency electric fields in the terahertz-range offer various advantages, as they can be applied contactlessly and homogeneously even to bulk samples using the intense radiation of a high power pulsed far-infrared laser. Furthermore, impurity ionization with terahertz radiation can be detected as photoconductive signal with a very high sensitivity in a wide range of electric field strengths

Interval total colorings of graphs

A total coloring of a graph $G$ is a coloring of its vertices and edges such that no adjacent vertices, edges, and no incident vertices and edges obtain the same color. An \emph{interval total $t$-coloring} of a graph $G$ is a total coloring of $G$ with colors $1,2,\...,t$ such that at least one vertex or edge of $G$ is colored by $i$, $i=1,2,\...,t$, and the edges incident to each vertex $v$ together with $v$ are colored by $d_{G}(v)+1$ consecutive colors, where $d_{G}(v)$ is the degree of the vertex $v$ in $G$. In this paper we investigate some properties of interval total colorings. We also determine exact values of the least and the greatest possible number of colors in such colorings for some classes of graphs.Comment: 23 pages, 1 figur

Fine structure and optical pumping of spins in individual semiconductor quantum dots

We review spin properties of semiconductor quantum dots and their effect on optical spectra. Photoluminescence and other types of spectroscopy are used to probe neutral and charged excitons in individual quantum dots with high spectral and spatial resolution. Spectral fine structure and polarization reveal how quantum dot spins interact with each other and with their environment. By taking advantage of the selectivity of optical selection rules and spin relaxation, optical spin pumping of the ground state electron and nuclear spins is achieved. Through such mechanisms, light can be used to process spins for use as a carrier of information

Manipulation of the Spin Memory of Electrons in n-GaAs

We report on the optical manipulation of the electron spin relaxation time in a GaAs based heterostructure. Experimental and theoretical study shows that the average electron spin relaxes through hyperfine interaction with the lattice nuclei, and that the rate can be controlled by the electron-electron interactions. This time has been changed from 300 ns down to 5 ns by variation of the laser frequency. This modification originates in the optically induced depletion of n-GaAs layer

Optical control of spin coherence in singly charged (In,Ga)As/GaAs quantum dots

Electron spin coherence has been generated optically in n-type modulation doped (In,Ga)As/GaAs quantum dots (QDs) which contain on average a single electron per dot. The coherence arises from resonant excitation of the QDs by circularly-polarized laser pulses, creating a coherent superposition of an electron and a trion state. Time dependent Faraday rotation is used to probe the spin precession of the optically oriented electrons about a transverse magnetic field. Spin coherence generation can be controlled by pulse intensity, being most efficient for (2n+1)pi-pulses.Comment: 5 pages, 4 figure

Good Pharmacovigilance Practice in the United States and the European Union

The article presents the results of a comparative analysis of Goodpharmacovigilance practices (GVP), developed by experts of the regulatory bodiesof the European Union (EU) and the United States. It is shown that the EU GVP cover almost all possible aspects of pharmacovigilance. It is noted that the disadvantages of EU GVP are difficulties in the correct understanding and interpretation of certain definitions and processes, as well as the complexity of the implementation in practice of a number of provisions, mainly related to the organization of the quality management system, including audit and inspection. As the basis for development of the Russian Rules GVP is recommended to use the GVP E

M. Kontsevich's graph complex and the Grothendieck-Teichmueller Lie algebra

We show that the zeroth cohomology of M. Kontsevich's graph complex is isomorphic to the Grothendieck-Teichmueller Lie algebra grt_1. The map is explicitly described. This result has applications to deformation quantization and Duflo theory. We also compute the homotopy derivations of the Gerstenhaber operad. They are parameterized by grt_1, up to one class (or two, depending on the definitions). More generally, the homotopy derivations of the (non-unital) E_n operads may be expressed through the cohomology of a suitable graph complex. Our methods also give a second proof of a result of H. Furusho, stating that the pentagon equation for grt_1-elements implies the hexagon equation

Aspects and issues of marketing authorisation and use of medicinal products for COVID-19 prevention during the pandemic

At the end of 2019, an outbreak of a new coronavirus began in the city of Wuhan (Hubei Province) in the People's Republic of China. The outbreak turned into a pandemic. In the shortest possible time, national and international manufacturers developed preventive COVID-19 vaccines, and the population was vaccinated. During pandemics, accelerated approval of vaccines is an important factor that shortens the time to market with the aim of mass vaccination. The experience of rapidly developing and introducing vaccines into routine practice is not only important for managing the current pandemic, but also valuable in case of extremely likely future ones. The aim of this study was to analyse the main issues associated with assessing the safety and efficacy of vaccines for COVID-19 prevention during their registration and widespread use amid the pandemic and ongoing SARS-CoV-2 evolution. The vaccines for COVID-19 prevention were developed and introduced into healthcare practice very rapidly and under the circumstances of the pandemic, and the use of these vaccines has surfaced a number of concerns requiring further research. The most important issues identified in the performed analysis include, but are not limited to the need for accelerated assessment of the safety and immunogenicity of new vaccines; the lack of immune correlates of protection against SARS-CoV-2; the waning of antibody immunity over time, motivating the need to determine revaccination and post-recovery vaccination timelines; and the emergence of mutant SARS-CoV-2 variants. One of noteworthy aspects is the need to develop recommendations for updating the strain composition of registered COVID-19 vaccines. According to the conclusions, the level of herd immunity, including vaccine-induced protection, plays a certain role in virus evolution during the pandemic. If COVID-19 becomes seasonal, which is a probable scenario, regular revaccination can be essential

Field Emission and Nanostructure of Carbon Films

The results of field emission measurements of various forms of carbon films are reported. It is shown that the films nanostructure is a crucial factor determining the field emission properties. In particular, smooth, pulsed-laser deposited amorphous carbon films with both high and low sp3 contents are poor field emitters. This is similar to the results obtained for smooth nanocrystalline, sp2-bonded carbon films. In contrast, carbon films prepared by hot-filament chemical vapor deposition (HE-CVD) exhibit very good field emission properties, including low emission turn-on fields, high emission site density, and excellent durability. HF-CVD carbon films were found to be predominantly sp2-bonded. However, surface morphology studies show that these films are thoroughly nanostructured, which is believed to be responsible for their promising field emission properties

Hyperfine-mediated transitions between a Zeeman split doublet in GaAs quantum dots: The role of the internal field

We consider the hyperfine-mediated transition rate between Zeeman split spin states of the lowest orbital level in a GaAs quantum dot. We separate the hyperfine Hamiltonian into a part which is diagonal in the orbital states and another one which mixes different orbitals. The diagonal part gives rise to an effective (internal) magnetic field which, in addition to an external magnetic field, determines the Zeeman splitting. Spin-flip transitions in the dots are induced by the orbital mixing part accompanied by an emission of a phonon. We evaluate the rate for different regimes of applied magnetic field and temperature. The rates we find are bigger that the spin-orbit related rates provided the external magnetic field is sufficiently low.Comment: 8 pages, 3 figure