عنوان

Special Polymers for Electronics and Optoelectronics

(Number (ISBN

9401105693

(Number (ISBN

9789401105699

Number

b594688

Title Proper

Special Polymers for Electronics and Optoelectronics

General Material Designation

[Book]

First Statement of Responsibility

edited by J.A. Chilton, M.T. Goosey.

Place of Publication, Distribution, etc.

Dordrecht

Name of Publisher, Distributor, etc.

Springer Netherlands : Imprint : Springer

Date of Publication, Distribution, etc.

1995

Specific Material Designation and Extent of Item

(XXIV, 351 pages)

Text of Note

1 Conductive polymers --; 1.1 Introduction --; 1.2 Traditional routes to conductive polymers --; 1.3 Conduction mechanisms --; 1.4 Conducting polymers --; 1.5 Applications --; 1.6 Conclusions and commercial prospects --; References --; 2 Electrodepositable resists --; 2.1 Introduction --; 2.2 Principles of electrodeposition --; 2.3 Polymers for electrodepositable resists --; 2.4 Electrodepositable resist formulation --; 2.5 Applications of electrodepositable resists --; 2.6 Summary and conclusions --; References --; 3 Polymeric Langmuir--Blodgett films --; 3.1 Introduction --; 3.2 Polymerization of Langmuir--Blodgett materials --; 3.3 Electrical properties --; 3.4 Optical properties --; 3.5 Concluding remarks --; References --; 4 Nonlinear materials --; 4.1 Introduction --; 4.2 Characterization --; 4.3?2 polymers --; 4.4?2 polymers --; 4.5 Polymeric devices --; References --; 5 Ferroelectric polymers --; 5.1 Introduction --; 5.2 Ferroelectric polymer materials --; 5.3 Properties of ferroelectric polymers --; 5.4 Applications of ferroelectric polymers --; 5.5 Conclusions --; References --; 6 Electroactive composites --; 6.1 Introduction --; 6.2 Composite designs --; 6.3 Diphasic models --; 6.4 Preparation and characterization --; 6.5 Composite poling --; 6.6 Applications --; References --; 7 Thermotropic liquid crystal polymers --; 7.1 Introduction --; 7.2 Liquid crystal polymer fundamentals --; 7.3 Processing --; 7.4 Property profiles --; 7.5 Applications --; 7.6 Outlook --; References --; 8 Photoconductive polymers --; 8.1 Introduction --; 8.2 General background --; 8.3 Materials --; 8.4 Experimental techniques --; 8.5 Applications --; References --; 9 Polymers for optical data storage --; 9.1 Introduction: the need for optical storage --; 9.2 The principles of optical storage --; 9.3 Polymers in the recording layer --; 9.4 Polymers in the manufacture of optical media --; 9.5 Polymers for optical heads --; 9.6 Polymers for cartridges --; 9.7 Other forms of optical storage --; 9.8 The future for polymers in optical data storage --; References.

Text of Note

Commercially successful fully synthetic polymeric materials were pro­ duced in the early years of this century, the first example being Bakelite. This was made from phenol and formaldehyde by Leo Bakeland in 1909. Before the end of the 1920s, a large number of other synthetic polymers had been created, including polyvinyl chloride and urea-formaldehyde. Today, there are literally hundreds of synthetic polymers commercially available with ranges of properties making them suitable for applications in many industrial sectors, including the electrical and electronics industries. In many instances the driving force behind the development of new materials actually came from the electronics industry, and today's advanced electronics would be inconceivable without these materials. For many years polymers have been widely used in all sectors of the electronics industry. From the early days of the semiconductor industry to the current state of the art, polymers have provided the enabling technologies that have fuelled the inexorable and rapid development of advanced electronic and optoelectronic devices.

Computer engineering.

Optical materials.

Surfaces (Physics)

Class number

Book number

edited by J.A. Chilton, M.T. Goosey.

J A Chilton

M T Goosey

Electronic name

[Book]

Y