This volume represents an introduction to a new world-wide attempt to review the history of technology, which is one of few since the pioneering publications of the 1960s. It takes an explicit archaeological focus to the study of the history of technology and adopts a more explicit socially-embedded view of technology than has commonly been the case in mainstream histories of technology. In doing so, it attempts to introduce a more radical element to explanations of technological change, involving magic, alchemy, animism - in other words, attempting to consider technological change in terms of the 'world view' of those involved in such change rather than from an exclusively western scientific perspective.

The study of forensic evidence using archaeology is a new discipline which has rapidly gained importance, not only in archaeological studies but also in the investigation of real crimes. Archaeological evidence is increasingly presented in criminal cases and has helped to secure a number of convictions.
Studies in Crime surveys methods of searching for and locating buried remains, their practical recovery, the decay of human and associated death scene materials, the analysis and identification of human remains including the use of DNA, and dating the time of death.
The book contains essential information for forensic scientists, archaeologists, police officers, police surgeons, pathologists and lawyers. Studies in Crime will also be of interest to members of the public interested in the investigation of death by unnatural causes, both ancient and modern.

The application of chemistry within archaeology is an important and fascinating area. It allows the archaeologist to answer such questions as "what is this artefact made of?", "where did it come from?" and "how has it been changed through burial in the ground?", providing pointers to the earliest history of mankind. Archaeological Chemistry begins with a brief description of the goals and history of archaeological science, and the place of chemistry within it. It sets out the most widely used analytical techniques in archaeology and compares them in the light of relevant applications. The book includes an analysis of several specific archaeological investigations in which chemistry has been employed in tracing the origins of or in preserving artefacts. The choice of these investigations conforms to themes based on analytical techniques, and includes chapters on obsidian, ceramics, glass, metals and resins. Finally, it suggests a future role for chemical and biochemical applications in archaeology. Archaeological Chemistry enables scientists to tackle the fundamental issues of chemical change in the archaeological materials, in order to advance the study of the past. It will prove an essential companion to students in archaeological science and chemistry, field and museum archaeologists, and all those involved in conserving human artefacts.

The use of chemistry in archaeology can help archaeologists answer questions about the nature and origin of the many organic and inorganic finds recovered through excavation, providing valuable information about the social history of humankind. This textbook tackles the fundamental issues in chemical studies of archaeological materials. Examining the most widely used analytical techniques in archaeology, the third edition of this comprehensive textbook features a new chapter on proteomics, capturing significant developments in protein recognition for dating and characterisation. The textbook has been updated to encompass the latest developments in the field. The textbook explores several archaeological investigations in which chemistry has been employed in tracing the origins of or in studying artefacts, and includes chapters on obsidian, ceramics, glass, metals and resins. It is an essential companion to students in archaeological science and chemistry, as well as to archaeologists, and those involved in conserving human artefacts.

Papers presented at a symposium Metals in Antiquity held in 1997 at Harvard University, which sought to explore the distribution of metals in the natural environment, and extractive metallurgy and fabrication processes, as well as the social context, use and deposition of artefacts. Subjects include the earliest use of iron in China (D Wagner), smelting and sacrifice in Greece and the Near East from the Bronze Age to the Classical period (S B Westover), Roman iron production in England (I Schruefer-Kolb), early 1600s silver exploitation in Scotland (E Photos-Jones, A J Hall, T Pollard, T K Meikle and A Newlands), the lead isotope method for tracing the sources of metal in the Western Hemisphere (A Macfarlane) .