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Conservation and Restoration of Glass is an in-depth guide to the materials and practices required for the care and preservation of glass objects. It provides thorough coverage of both theoretical and practical aspects of glass conservation. This new edition of Newton and Davison's original book, Conservation of Glass, includes sections on the nature of glass, the historical development and technology of glassmaking, and the deterioration of glass. Professional conservators will welcome the inclusion of recommendations for examination and documentation. Incorporating treatment of both excavated glass and historic and decorative glass, the book provides the knowledge required by conservators and restorers and is invaluable for anyone with glass objects in their care.
Conservation and Restoration of Glass is an in-depth guide to the materials and practices required for the care and preservation of glass objects. It provides thorough coverage of both theoretical and practical aspects of glass conservation.This new edition of Newton and Davison's original book, Conservation of Glass, includes sections on the nature of glass, the historical development and technology of glassmaking, and the deterioration of glass. Professional conservators will welcome the inclusion of recommendations for examination and documentation. Incorporating treatment of both excavated glass and historic and decorative glass, the book provides the knowledge required by conservators and restorers and is invaluable for anyone with glass objects in their care.
Much progress has been made in scattering theory since the publication of the first edition of this book fifteen years ago, and it is time to update it. Needless to say, it was impossible to incorporate all areas of new develop ment. Since among the newer books on scattering theory there are three excellent volumes that treat the subject from a much more abstract mathe matical point of view (Lax and Phillips on electromagnetic scattering, Amrein, Jauch and Sinha, and Reed and Simon on quantum scattering), I have refrained from adding material concerning the abundant new mathe matical results on time-dependent formulations of scattering theory. The only exception is Dollard's beautiful "scattering into cones" method that connects the physically intuitive and mathematically clean wave-packet description to experimentally accessible scattering rates in a much more satisfactory manner than the older procedure. Areas that have been substantially augmented are the analysis of the three-dimensional Schrodinger equation for non central potentials (in Chapter 10), the general approach to multiparticle reaction theory (in Chapter 16), the specific treatment of three-particle scattering (in Chapter 17), and inverse scattering (in Chapter 20). The additions to Chapter 16 include an introduction to the two-Hilbert space approach, as well as a derivation of general scattering-rate formulas. Chapter 17 now contains a survey of various approaches to the solution of three-particle problems, as well as a discussion of the Efimov effect."
The normal business of physicists may be schematically thought of as predic ting the motions of particles on the basis of known forces, or the propagation of radiation on the basis of a known constitution of matter. The inverse problem is to conclude what the forces or constitutions are on the basis of the observed motion. A large part of our sensory contact with the world around us depends on an intuitive solution of such an inverse problem: We infer the shape, size, and surface texture of external objects from their scattering and absorption of light as detected by our eyes. When we use scattering experiments to learn the size or shape of particles, or the forces they exert upon each other, the nature of the problem is similar, if more refined. The kinematics, the equations of motion, are usually assumed to be known. It is the forces that are sought, and how they vary from point to point. As with so many other physical ideas, the first one we know of to have touched upon the kind of inverse problem discussed in this book was Lord Rayleigh (1877). In the course of describing the vibrations of strings of variable density he briefly discusses the possibility of inferring the density distribution from the frequencies of vibration. This passage may be regarded as a precursor of the mathematical study of the inverse spectral problem some seventy years later."
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