One of the main outcomes of the eleven meetings of the Working Party was the recognition of the importance of interdisciplinary studies linking regional geochemistry with plant, animal and human health. The effects of major element deficiencies or excesses on plant health are well known; this is not the case for trace elements. In fact, rapid and reliable analytical methods for determining trace element abundances have only recently become available, and it is to be expected that important new information on trace element levels will be forthcoming. This, however, is only part of the problem because other factors such as element speciation, uptake and transmission may be more significant than total concentration. The pathways of elements from crops to animals are relatively well defined, but the aetiology of diseases attributable to elemental inadequacies or excesses is generally quite complex. Nevertheless, there is good evidence for diseases in livestock in the British Isles induced by deficiencies of Cu, Se and Co and Mo excess. On a world scale there is also convincing data on the effect of Na, P and I deficiencies and F excess on animal health. What is generally lacking, however, is adequate interaction between geochemists and biochemists, veterinary scientists and other concerned with animal health. Interpretation of geochemical data is complex as are connections between elemental abundances and the health of animals.

Although this is a handbook for policy and regulation, the major part of it is filled with data on the three heavy metals that served as examples: mercury, cadmium and lead. Their stocks, productions, prices, trade flows, uses and applications, recovery and recycling, as well as their (eco)toxicological characteristics have been collected and presented to their fullest extent. In addition, they are thoroughly analysed for consistency, future developments and trends and, of course, their consequences for sustainable development and future policy and regulation. The second part, on policy and regulation, begins with an extensive and fundamental consideration on the characteristics of a sustainable heavy metals policy, whereby innovative policy tools are developed. In many aspects, these considerations are also valid for other metals and even non-metallic persistent substances. Addressing the European Union in particular, its policy-making structure and practice are critically analysed, in order to develop feasible and viable guidelines for long-, medium- and short-term EU policy measures. The results of this exercise are then applied to the three heavy metals. In each of these three chapters, all existing EU measures are presented in detail and confronted with better practices elsewhere, resulting in many suggestions and recommendations for the future. In the last chapter, the main conclusions and recommendations are carefully summarised. Together with a very extended table of contents, this makes the book easily accessible, in spite of its volume. This Handbook is a must for policy-makers and administrators at all levels, as well as for their counterparts in a wide variety of industries. In addition, it is well-suited for environmental science courses at academic or higher professional level.

Although this is a handbook for policy and regulation, the major part of it is filled with data on the three heavy metals that served as examples: mercury, cadmium and lead. Their stocks, productions, prices, trade flows, uses and applications, recovery and recycling, as well as their (eco)toxicological characteristics have been collected and presented to their fullest extent. In addition, they are thoroughly analysed for consistency, future developments and trends and, of course, their consequences for sustainable development and future policy and regulation. The second part, on policy and regulation, begins with an extensive and fundamental consideration on the characteristics of a sustainable heavy metals policy, whereby innovative policy tools are developed. In many aspects, these considerations are also valid for other metals and even non-metallic persistent substances. Addressing the European Union in particular, its policy-making structure and practice are critically analysed, in order to develop feasible and viable guidelines for long-, medium- and short-term EU policy measures. The results of this exercise are then applied to the three heavy metals. In each of these three chapters, all existing EU measures are presented in detail and confronted with better practices elsewhere, resulting in many suggestions and recommendations for the future. In the last chapter, the main conclusions and recommendations are carefully summarised. Together with a very extended table of contents, this makes the book easily accessible, in spite of its volume. This Handbook is a must for policy-makers and administrators at all levels, as well as for their counterparts in a wide variety of industries. In addition, it is well-suited for environmental science courses at academic or higher professional level.

One of the main outcomes of the eleven meetings of the Working Party was the recognition of the importance of interdisciplinary studies linking regional geochemistry with plant, animal and human health. The effects of major element deficiencies or excesses on plant health are well known; this is not the case for trace elements. In fact, rapid and reliable analytical methods for determining trace element abundances have only recently become available, and it is to be expected that important new information on trace element levels will be forthcoming. This, however, is only part of the problem because other factors such as element speciation, uptake and transmission may be more significant than total concentration. The pathways of elements from crops to animals are relatively well defined, but the aetiology of diseases attributable to elemental inadequacies or excesses is generally quite complex. Nevertheless, there is good evidence for diseases in livestock in the British Isles induced by deficiencies of Cu, Se and Co and Mo excess. On a world scale there is also convincing data on the effect of Na, P and I deficiencies and F excess on animal health. What is generally lacking, however, is adequate interaction between geochemists and biochemists, veterinary scientists and other concerned with animal health. Interpretation of geochemical data is complex as are connections between elemental abundances and the health of animals.

This is a reproduction of a book published before 1923. This book may have occasional imperfections such as missing or blurred pages, poor pictures, errant marks, etc. that were either part of the original artifact, or were introduced by the scanning process. We believe this work is culturally important, and despite the imperfections, have elected to bring it back into print as part of our continuing commitment to the preservation of printed works worldwide. We appreciate your understanding of the imperfections in the preservation process, and hope you enjoy this valuable book. ++++ The below data was compiled from various identification fields in the bibliographic record of this title. This data is provided as an additional tool in helping to ensure edition identification: ++++ Notes On Experimental Dynamics I. Thornton Osmond Edwin K. Myers, 1887 Science; Mechanics; Dynamics; General; Dynamics; Kinematics; Science / Mechanics / Dynamics / General