Applications of Analytical Techniques to the Characterization of Materials
Seiten
1992
|
1991 ed.
Kluwer Academic/Plenum Publishers (Verlag)
978-0-306-44189-9 (ISBN)
Kluwer Academic/Plenum Publishers (Verlag)
978-0-306-44189-9 (ISBN)
Over the last several years, the field of materials science has witnessed an explosion of new, advanced materials. Bulk materials, for example, are being synthesized and applica tions found for them, while still other materials are being synthesized as thin films for yet still more new (and in some cases, as yet unknown) applications.
Over the last several years, the field of materials science has witnessed an explosion of new, advanced materials. They encompass many uses and include superconductors, alloys, glasses, and catalysts. Not only are there quite a number of new enhies into these generic classes of materials, but the materials themselves represent a wide array of physical forms as well. Bulk materials, for example, are being synthesized and applica tions found for them, while still other materials are being synthesized as thin films for yet still more new (and in some cases, as yet unknown) applications. The field continues to expand with (thankfully!) no end in sight as to the number of new possibilities. As work progresses in this area, there is an ever increasing demand for knowing not only what material is formed as an end product but also details of the route by which it is made. The knowledge of reaction mechanisms in their synthesis many times allows a researcher to tailor a preparative scheme to either arrive at the final product in a purer state or with a better yield. Also, a good fundamental experimental knowledge of impuri ties present in the final material helps the investigator get more insight into making it.
Over the last several years, the field of materials science has witnessed an explosion of new, advanced materials. They encompass many uses and include superconductors, alloys, glasses, and catalysts. Not only are there quite a number of new enhies into these generic classes of materials, but the materials themselves represent a wide array of physical forms as well. Bulk materials, for example, are being synthesized and applica tions found for them, while still other materials are being synthesized as thin films for yet still more new (and in some cases, as yet unknown) applications. The field continues to expand with (thankfully!) no end in sight as to the number of new possibilities. As work progresses in this area, there is an ever increasing demand for knowing not only what material is formed as an end product but also details of the route by which it is made. The knowledge of reaction mechanisms in their synthesis many times allows a researcher to tailor a preparative scheme to either arrive at the final product in a purer state or with a better yield. Also, a good fundamental experimental knowledge of impuri ties present in the final material helps the investigator get more insight into making it.
1. Application of Combined X-Ray Photoelectron/Auger Spectroscopy to Studies of Inorganic Materials.- 2. X-Ray Photoelectron and Ion Scattering Spectroscopic Studies of Composites.- 3. Diffraction and Mössbauer Spectroscopic Characterization of Mixed Metal Oxides.- 4. Characterization of High Temperature Superconductors with Raman Spectroscopy.- 5. Applications of AC Complex Impedance Spectroscopy to Fast Ion Conducting Lithium Silicate Gels.- 6. Applications of the Mössbauer Effect to the Characterization of Materials.- 7. Laser Mass Spectral Analysis of Rubber Surfaces.- 8. The Uses of Thermogravimetric Analysis and Infrared Spectroscopy for Characterizating Supported Catalysts.
Zusatzinfo | IX, 192 p. |
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Verlagsort | New York |
Sprache | englisch |
Maße | 178 x 254 mm |
Themenwelt | Naturwissenschaften ► Chemie ► Analytische Chemie |
ISBN-10 | 0-306-44189-6 / 0306441896 |
ISBN-13 | 978-0-306-44189-9 / 9780306441899 |
Zustand | Neuware |
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