Application of Particle and Laser Beams in Materials TechnologyP. Misaelides The development of advanced materials with preselected properties is one of the main goals of materials research. Of especial interest are electronics, high-temperature and supemard materials for various applications, as well as alloys with improved wear, corrosion and mechanical resistance properties. The technical challenge connected with the production of these materials is not only associated with the development of new specialised preparation techniques but also with quality control. The energetic charged particle, electron and photon beams offer the possibility of modifying the properties of the near-surface regions of materials without seriously affecting their bulk, and provide unique analytical tools for testing their qUality. This volume includes most of the lectures and contributions delivered at the NATO-funded Advanced Study Institute "Application of Particle and Laser Beams in Materials Technology", which was held in Kallithea, Chalkidiki, in Northern Greece, from the 8th to the 21st of May, 1994 and attended by 73 participants from 21 countries. The aim of this ASI was to provide to the participants an overview of this rapidly expanding field. Fundamental aspects concerning the interactions and collisions on atomic, nuclear and solid state scale were presented in a didactic way, along with the application of a variety of techniques for the solution of problems ranging from the development of electronics materials to corrosion research and from archaeometry to environmental protection. |
Contents
II | 1 |
III | 21 |
IV | 37 |
V | 53 |
VI | 77 |
VII | 95 |
VIII | 115 |
IX | 133 |
XXVIII | 415 |
XXIX | 427 |
XXX | 437 |
XXXI | 443 |
XXXII | 463 |
XXXIII | 471 |
XXXIV | 477 |
XXXV | 485 |
Other editions - View all
Application of Particle and Laser Beams in Materials Technology P. Misaelides No preview available - 2010 |
Application of Particle and Laser Beams in Materials Technology P. Misaelides No preview available - 2013 |
Common terms and phrases
accelerators activation alloys analysis angle annealing Beams in Materials calculated cascade chemical collision concentration corrosion crystal density deposition depth profiling depth resolution detection detector determined diffusion effects elastic recoil detection electron beam elements emission energy loss etching EXAFS excitation experimental FIGURE function GaAs glass hydrogen Instr interaction intercalation interface ion beam ion beam analysis ion beam mixing ion bombardment ion implantation ionisation irradiation laser ablation Laser Beams lattice layer mass Materials Technology measurements metal Meth method Misaelides mixing MoS2 Nucl nuclear reaction optical oxide oxygen parameters peak phase phonon Phys plasma polymer produced projectile protons radiation Raman Raman scattering recoil resonance Rutherford backscattering Rutherford scattering sample scanning scattering semiconductor shown in Fig silicon solid spectra spectrometry spectroscopy spectrum sputtering stoichiometry stopping power structure substrate superconducting surface technique temperature thermal thickness thin films velocity X-ray yield zeolite