Self-Organization During Friction: Advanced Surface-Engineered Materials and Systems Design

German Fox-Rabinovich McMaster University
George E. Totten Portland State University
Self-Organization During Friction: Advanced Surface-Engineered Materials and Systems Design
Publication Type List Price
Reference $154.95 / £98
Publication Date Imprint
9/18/2006 CRC
Disciplines ISBN
Nanomaterials 9781574447194
Number of Pages Buy with discount
459 buy
   
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Description

In our present era of nanoscience and nanotechnology, new materials are poised to take center stage in dramatically improving friction and wear behavior under extreme conditions. Compiled by two eminent experts, Self-Organization During Friction: Advanced Surface-Engineered Materials and Systems Design details the latest advances and developments in self-organization phenomena, physical and chemical aspects of friction, and new methods of friction control using advanced materials and coatings.

Approaching nanomaterials from the perspective of irreversible thermodynamics and self-organization, this work presents a new approach to developing an emerging generation of surface-engineered self-adaptive nanostructured materials. The book demonstrates how nanoscale structure, synergistic alloying, and the non-equilibrium state of surface-engineered layers affects the capacity of these next-generation materials to resist wear in heavily loaded tribosystems. These links become clear through discussions on non-equilibrium thermodynamics, tribological compatibility, and self-organization phenomena during friction. International experts also supply cutting-edge information on nanocrystalline and nanolaminated coatings while tracing new trends in materials science and surface engineering at the nanoscale.

By combining detailed discussions on the underlying theory with practical examples of extreme tribological applications, Self-Organization During Friction outlines a forward-looking strategy for developing and implementing new surface-engineered materials that promise previously unattainable levels of tribological performance.

Table of Contents

Self-Organization during Friction and Principles of Friction Control. Tribological Compatibility and Nanotribological Characteristics to Evaluate Surface Properties during Friction. Self-Organization and Structural Adaptation of Heavily Loaded Tribosystems. Adaptive Surface-Engineered Materials and Systems. Index.

Contributors

Contributor Gershman, Iosif S., Scientific Research Institute, Moscow. Russia Contributor Bushe, Nicolay A., Scientific Research Institute, Mascow, Russia Contributor Kovalev, Anatoliy I., Contributor Yamamoto, Kenji, Kobe Steele Ltd., Japan Contributor Velduis, Stephen, McMaster University, Hamilton, Ontario, Canada Contributor Shuster, Lev, Ufa Avia Institute, Russia Contributor Bruhis, Michael, McMaster University, Hamilton, Ontario Contributor Wainstein, Dmitry L., Surface Phenomena Researches Group, Moscow, Russia Contributor Beake, Ben D., Micro Materials Ltd., Wrexham, England Contributor Endrino, Jose, Lawrence Berkeley National Lab, California, USA Editor 1 Fox-Rabinovich, German, McMaster University, Hamilton, Ontario, Canada Editor 2 Totten, George E., Portland State University, Oregon, USA
by siebo last modified September 21, 2009 - 08:36
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Features

  • - Demonstrates the unique nature of nanomaterials through irreversible thermodynamics and self-organization concepts
  • - Outlines new approaches for developing novel surface-engineered nanostructured materials for extreme applications
  • - Introduces novel ideas related to the nonequilibrium states of nanostructured materials in relation to their tribological and service properties
  • - Builds an understanding of new trends in materials science and surface engineering of nano-scaled materials
  • - Explores adaptive surface-engineered materials able to form stable protective or low-friction nano-scaled tribofilms