High-Order Harmonics Generation in Plasmas, 1st ed. 2022 Resonance Processes, Quasi-Phase-Matching, and Nanostructures Springer Series on Atomic, Optical, and Plasma Physics Series, Vol. 122
This book comprises a detailed consideration of novel approaches developed in the field of frequency conversion of laser sources in laser-induced plasmas during the last few years. The aim of the book is to support researchers and other readers in their development in the area of high-order nonlinear spectroscopy. Particularly, the advanced studies of nanoparticles and quantum dots for the formation of new sources of radiation in different short-wavelength spectral ranges show the ways to further implement the specific features of small-sized species in a relatively new field of study?laser ablation induced high-order harmonics generation spectroscopy.
Researchers involved in the development of new methods of frequency conversion will benefit from finding the most recent advances in this field. Undergraduate students will discover interesting information about recent findings in plasma harmonic research. Additionally, the usefulness of the book will be demonstrated by the potential applications of the new knowledge developed during recent years for ultrafast pulse generation using the proposed schemes of plasma-light interaction. Thus, the audience may also include those researchers involved in state-of-the-art developments in attophysics. Additionally, any professionals interested in the application of the advanced techniques for material science will also benefit from updating their knowledge of new methods of material studies using high-order nonlinear spectroscopy.
Discusses broader consideration of nonlinear optical aspects of light–plasma interactions
Provides a set of studies of the formation of coherent short-wavelength sources
Discusses applications of the quasi-phase matching concept in laser-induced plasmas
Date de parution : 08-2023
Ouvrage de 271 p.
15.5x23.5 cm
Date de parution : 08-2022
Ouvrage de 271 p.
15.5x23.5 cm