High-brightness Metal Vapour Lasers Volume I: Physical Fundamentals and Mathematical Models
Auteurs : Batenin V. M., Buchanov V. V., Boichenko A. M., Kazaryan M. A., Klimovskii I. I., Molodykh E. I.
High brightness metal vapor lasers have become the most bright and powerful in the visible spectral range among all existing laser types, resulting in numerous applications ranging from purely fundamental research to practical application in large-scale commercial problems such as isotope selection. This book presents a full series of fundamental problems on the development of physical fundamentals and mathematical models for practical realization of a high-power laser radiation on self-contained transitions in metal atoms. It is the first fundamental review on physics and the technique of high-brightness metal vapor lasers.
Introduction. The devices and methods of creating metal vapors. Excitation schemes and its effect on the characteristics of the generation of self-heating copper vapor lasers. Excitation blocks of lasers on self-terminating transitions of metal atoms. Repetitively pulsed lasers on self-terminating transitions of metal atoms. The results of analytical studies on laser self-terminating transitions of metal atoms. Numerical studies of pulsed metal vapor lasers. Numerical simulation of pulsed-periodic MVL considering the inhomogeneous distribution of the plasma parameters (heterogeneity level) cross section GDT. Modeling of copper vapor lasers. Lasers with a modified kinetics (kinetically enhanced lasers).
V. M. Batenin, V. V. Buchanov, A. M. Boichenko, M. A. Kazaryan, I. I. Klimovskii, E. I. Molodykh
Date de parution : 06-2020
15.6x23.4 cm
Date de parution : 02-2017
Ouvrage de 600 p.
15.6x23.4 cm
Disponible chez l'éditeur (délai d'approvisionnement : 15 jours).
Prix indicatif 220,72 €
Ajouter au panierThèmes de High-brightness Metal Vapour Lasers :
Mots-clés :
Copper Vapor Laser; Metal Vapour Lasers; copper; Excitation Pulse; vapor; Copper Atoms; excitation; Neon Pressure; pulse; Buffer Gas; atom; Metastable Levels; self-contained; Pulse Repetition Frequency; transitions; Average Lasing Power; buffer; Interpulse Interval; gas; Metastable Atoms; storage; Interpulse Period; Electron Temperature; Buffer Gas Pressure; Storage Capacitor; Excitation Circuit; Discharge Circuit; Specific Energy Output; Axial Zone; Discharge Gap; Lasing Characteristics; Transverse Discharge; Self-contained Transitions; Electron Concentration; Vapour Lasers