Joshua Pelleg received his B.S. in Chemical Engineering Technion Institute of Technology, Haifa, Israel, M. S. in Metallurgy, Illinois Institute of Technology, Chicago, IL, USA and Ph. D. in Metallurgy, University of Wisconsin, Madison, WI. He is with Ben Gurion University of the Negev, Materials Engineering Department, Beer Sheva, Israel since 1970, was among the founders of the department, and its second chairman. Professor Pelleg was the recipient of the Sam Ayrton Chair in Metallurgy. He has taught ever since the subjects of Mechanical Properties of Materials, Diffusion in Solids and Defects in Solids. He has chaired several University committees and served four terms as the Chairman of Advanced Studies in Ben Gurion University. Prior to arriving to BGU, Pelleg acted as Assistant Professor and then Associate Professor in the Department of Materials and Metallurgy, University of Kansas, Lawrence, KS, USA. Professor Pelleg was Visiting Professor in: Department of Metallurgy, Iowa State University, Institute for Atomic Research, US Atomic Energy Commission, Ames, IA, USA, McGill University, Montreal, QC, Canada, Tokyo Institute of Technology, Applied Electronics Dept., Nagatsuta Campus, Yokohama, Japan and in Curtin University, Department of Physics, Perth, Australia. Among his non-academic research and industrial experience one can note: Chief Metallurgist in Urdan Netallurgical Works LTD., Netanya, Israel, Research Engineer in International Harvester, Manufacturing Research, Chicago IL., Associate Research Officer, National Research Council of Canada, Structures and Materials, National Aeronautical Establishment, Ottawa, ON, Physics Senior Research Scientist, Nuclear Research Center, Beer Sheva, Israel. Materials Science Division, Argonne National Labs, Argonne, IL, USA., Atomic Energy of Canada, Chalk River, Ont. Canada, Visiting Scientist, CSIR, National Accelerator Centre, Van de Graaf Group Faure, South Africa, Bell Laboratories, Murray Hill, NJ, USA, GTE Laboratories, Waltham, MA, USA. His current research interests are diffusion in solids, thin film deposition and properties (mostly by sputtering) and characterization of thin films among them various silicides.

Part A Fundamentals of Diffusion
1 Macroscopic Diffusion
2 Microscopic (or Atomic) Diffusion
3 Defects in Materials
4 Mechanism of Diffusion
5 Self Diffusion, Solute Diffusion, Diffusion in Ionic Crystals and Correlation Effects
6 Interdiffusion
7 Diffusion in Grain Boundaries
8 Diffusion in Dislocations
9 Experimental Methods and Procedures
10 Empirical Rules
Part B Diffusion in Ceramics (Experimental)

11 Diffusion in Alumina Single Crystals
12 Diffusion in Silicon Carbide (Carborundum)
13 Diffusion in MgO (Magnesia or Periclase)
14 Diffusion in ZrO₂ (Zirconia) Single Crystals
15 Diffusion in Si₃N₄ Single Crystals
Index

This textbook provides an introduction to changes that occur in solids such as ceramics, mainly at high temperatures, which are diffusion controlled, as well as presenting research data. Such changes are related to the kinetics of various reactions such as precipitation, oxidation and phase transformations, but are also related to some mechanical changes, such as creep.

The book is composed of two parts, beginning with a look at the basics of diffusion according to Fick's Laws. Solutions of Fick's second law for constant D, diffusion in grain boundaries and dislocations are presented along with a look at the atomistic approach for the random motion of atoms. In the second part, the author discusses diffusion in several technologically important ceramics. The ceramics selected are monolithic single phase ones, including: A1₂O₃, SiC, MgO, ZrO₂ and Si₃N₄. Of these, three refer to oxide ceramics (alumina, magnesia and zirconia). Carbide based ceramics are represented by the technologically very important Si-carbide and nitride based ceramics are represented by Si-nitride which has been important in high temperature ceramics and gas turbine applications.

The author presents a clear, concise and relatively comprehensive treatment of diffusion in ceramics for use by those at an advanced undergraduate level and beyond. It supports understanding of the basic behavior of materials and how to relate observed physical properties to microscopic understanding. The book also provides researchers with a handy collation of data relating to diffusion in ceramics and supports a fundamental understanding of atomic movements.