Journal of Russian Laser Research is based on the best Russian research in the field of lasers. It is based on research selected for its timeliness and importance to this rapidly growing field. Research carried out under the auspices of the prestigious P. N. Lebedev Physical Institute of the Russian Academy of Sciences will form the core of this journal. Coverage includes carefully selected current research in traditional areas such as laser physics; nonlinear optics; laser-stimulated chemistry; laser applications; laser spectroscopy; laser interactions with matter and plasma; laser pumping; properties of laser beams; and solid-state, gas, liquid, chemical, and semiconductor lasers, as well as in new areas such as quantum optics and quantum information processing. All articles are peer-reviewed. More information is available at the editors' website via the following link: http://sites.lebedev.ru/JRLR/show.php?page_id=0
Journal of Russian Laser Research
Description
Identifiers
ISSN | 1071-2836 |
e-ISSN | 1573-8760 |
DOI | 10.1007/10946.1573-8760 |
Publisher
Springer US
Additional information
Data set: Springer
Articles
Journal of Russian Laser Research > 2019 > 40 > 5 > 452-466
A “transparent point” is a particular value of a governing parameter in a nontranslationally invariant system that makes the system “almost” translationally invariant. This concept was introduced recently in the context of the discrete nonlinear Schrödinger (DNLS) equation with saturable nonlinearity — it was discovered that a tuning of the lattice spacing parameter h in this model affects the soliton...
Journal of Russian Laser Research > 2019 > 40 > 5 > 496-502
We discuss the possibility to formulate the dynamics of spin states described by the Schr¨odinger equation for pure states and the von Neumann equation (as well as the GKSL equation) for mixed states in the form of quantum kinetic equations for probability distributions. We review an approach to the spin-state description by means of the probability distributions of dichotomic random variables.
Journal of Russian Laser Research > 2019 > 40 > 5 > 474-485
We investigate the interaction between a test monochromatic wave and semibounded plasma formed by multiphoton ionization of gas atoms. Under conditions where photoelectron distribution is isotropic and has a narrow peak in energy, the field in the plasma is represented by two contributions. The first of them arises from a pole in the complex plane of wave numbers and decays exponentially deeper into...