Engineers in the mining industry often must solve problems while in the field at prospects, projects, or places far from any personal bookshelf, company office, or public or private library. And it isn’t always feasible to bring along the voluminous authoritative books on mining topics so familiar to the profession. This handbook, then, is designed to fill the technical reference gap for the mobile professional who is away from the normal workplace with its comprehensive store of technical information and resources. It is a distillation of key technical information from the mining literature.

The study of carbon ate- si lie tclastic mixed sequences has seen an increase in the number of investigations that focus on mixed settings as pan of the continuum between the carbonate and clastic end members. The level of interest in such mixed sequences has been reflected in recent years by sessions at national meetings that dealt specifically with the topic, and also by recent publications

Quantitative modeling techniques and methods are central to the study and development of process engineering, and mineral processing is no exception. Models in mineral processing have been difficult to develop because of the complexity of the unit operations that are used in virtually all mineral recovery systems. Chief among these difficulties is the fact that the feed material is invariably a particulate solid. Many of the conventional mathematical modeling techniques that are commonly used for process equipment have limited application to particulate systems and models for most unit operations in mineral processing have unique features. Common ground is quite difficult to find. The one obvious exception is the population balance technique and this forms a central thread that runs throughout the modeling techniques that are described in this book. The models that are described are certainly incomplete in many respects, and these will be developed and refined by many researchers during the years ahead. Nevertheless, the models are useful for practical quantitative work and many have been widely used to assist in the design of new equipment and processes. Some of the newer models have not yet been seriously tested in the industrial environment <...>

Geophysics, or physics modelling of geological phenomena, is as old and as established as geoscience itself. The statistical physics modelling of various geophysical phenomena, earthquake in particular, is comparatively recent. This book intends to cover these recent developments in modelling various geophysical phenomena, including the imposing classic phenomenon of earthquakes, employing various statistical physical ideas and techniques. This first book on statistical physics modelling of geophysical phenomena contains extensive reviews by almost all the leading experts in the field and should be widely useful to the graduate students and researchers in geoscience and statistical physics. It grew out of the lecture notes from a workshop on “Models of Earthquakes: Physics Approaches”, held in Saha Institute of Nuclear Physics, Kolkata, under the auspices of its Centre for Applied Mathematics and Computational Science in December 2005. The book is divided in four parts. In the first part, tutorial materials are