Characterization of High Tc Materials and Devices by Electron Microscopy

Hardback

Main Details

Title Characterization of High Tc Materials and Devices by Electron Microscopy
Authors and Contributors      Edited by Nigel D. Browning
Edited by Stephen J. Pennycook
Physical Properties
Format:Hardback
Pages:406
Dimensions(mm): Height 244,Width 170
Category/GenreElectricity, electromagnetism and magnetism
Materials science
ISBN/Barcode 9780521554909
ClassificationsDewey:537.6231
Audience
Professional & Vocational
Illustrations 3 Tables, unspecified; 152 Halftones, unspecified; 115 Line drawings, unspecified

Publishing Details

Publisher Cambridge University Press
Imprint Cambridge University Press
Publication Date 6 July 2000
Publication Country United Kingdom

Description

This is a clear and up-to-date account of the application of electron-based microscopies to the study of high-Tc superconductors. Written by leading experts, this compilation provides a comprehensive review of scanning electron microscopy, transmission electron microscopy and scanning transmission electron microscopy, together with details of each technique and its applications. Introductory chapters cover the basics of high-resolution transmission electron microscopy, including a chapter devoted to specimen preparation techniques, and microanalysis by scanning transmission electron microscopy. Ensuing chapters examine identification of new superconducting compounds, imaging of superconducting properties by low-temperature scanning electron microscopy, imaging of vortices by electron holography and electronic structure determination by electron energy loss spectroscopy. The use of scanning tunnelling microscopy for exploring surface morphology, growth processes and the mapping of superconducting carrier distributions is discussed. Final chapters consider applications of electron microscopy to the analysis of grain boundaries, thin films and device structures. Detailed references are included.

Reviews

'... a useful and nearly comprehensive guide to current work in the subject.' J. P. Davey, Contemporary Physics