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3 edition of Optical techniques to characterize polymer systems found in the catalog.

Optical techniques to characterize polymer systems

Optical techniques to characterize polymer systems

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  • 26 Currently reading

Published by Elsevier, Distributors for the United States and Canada, Elsevier Science Pub. Co. in Amsterdam, New York, New York, N.Y .
Written in English

    Subjects:
  • Polymers -- Optical properties.,
  • Spectrum analysis.

  • Edition Notes

    Includes bibliographical references.

    Statementedited by Heinz Bässler.
    SeriesStudies in polymer science ;, 5
    ContributionsBässler, Heinz.
    Classifications
    LC ClassificationsQD381.9.O66 O68 1989
    The Physical Object
    Paginationx, 609 p. :
    Number of Pages609
    ID Numbers
    Open LibraryOL2202046M
    ISBN 100444881948
    LC Control Number89023753

      COMPARISON B/W POFs & GOFs POLYMER OPTICAL FIBER Plastic optical fiber, polymer optical fiber is an optical fiber which is made out of plastic. It comprises of PMMA as the core that facilitates the transmission of light, and fluorinated polymers as the cladding material. Simpler and less expensive components. Greater flexibility and light.   Discerning the properties of polymers and polymer-based materials requires a good understanding of characterization. This revised and updated text provides a comprehensive survey of characterization methods within its simple, concise chapters. Polymer Characterization: Physical Techniques, provides an overview of a wide variety of characterization methods, 4/5(1).

    Three-dimensional networks can be hydrophilic and/or hygroscopic. Optical, mechanical, and electrical properties of these materials encompass many fields of technology. Composites of carbon nanotubes (CNTs) in polymeric materials have attracted considerable attention in the research and industrial communities due to their unique optical, mechanical, and electrical Cited by: 1. Mathematics and computer science skills, especially the ability to understand and apply statistical techniques; Analytical instrumentation techniques to characterize properties and performance of materials; Critical thinking, problem solving, and analytical skills to determine which tests to conduct and to interpret the results of those tests.

    Surfaces and interfaces of polymers play an important role in most of the application areas of polymers, e.g. moulds, foils, thin films, coatings, adhesive joints, blends, composites, biomaterials or applications in micro- and nanotechnology. Therefore it is very important to be able to. Describes techniques applied to characterize surfactant systems, such as surfactant-stabilized colloids, micelles, microemulsions, emulsions and foams in both aqueous and nonaqueous fluids. This text intends to probe adsorption and wetting phenomena at interfaces, including solid-liquid, liquid-vapour and liquid-liquid.


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Optical techniques to characterize polymer systems Download PDF EPUB FB2

ISBN: OCLC Number: Description: x, pages: illustrations ; 25 cm. Contents: FTIR-spectroscopy of polymers (J.L. Koenig). Optical techniques to characterize polymer systems, H. Bassler, ed., Elsevier, New York,pp. Price: $Author: Arnost Reiser. Optical Techniques for Solid-State Materials Characterization provides detailed descriptions of basic and advanced optical techniques commonly used to study materials, from the simple to the complex.

The book explains how to use these techniques to acquire, analyze, and interpret data for gaining insight into material properties.5/5(2). Polymer Characterization: Physical Techniques, provides an overview of a wide variety of characterization methods, which makes it an excellent textbook and reference.

It starts with a description of basic polymer science, providing a solid foundation from which to understand the key physical characterization techniques. For polymer blends, a minimum domain size of 1 μm can be examined in the optical microscope using one or more techniques such as phase contrast, polarized light, incident, and bright field.

In-line Optical Techniques to Characterize the Polymer Extrusion Article (PDF Available) in Polymer Engineering and Science 54(2) February. optical characterization of solids Download optical characterization of solids or read online books in PDF, EPUB, Tuebl, and Mobi Format. Click Download or Read Online button to get optical characterization of solids book now.

This site is like a library, Use search box in the widget to get ebook that you want. Today, various techniques are available to characterize the elastic-mechanical properties of materials, including microindentation (or microhardness), which provides the Knoop hardness H k and the Vickers hardness H v, and then, indirectly, the Young’s modulus E; the torsion pendulum, which provides information on the shear modulus G; the Cited by: 2.

This chapter gives an introduction to the book. Starting with a brief history of communication and optical communication in particular the background is prepared for the rapidly developing techniques in polymer-optical fibres. We conclude the chapter with a list of the chapters to come and the motivation behind each of them.

Describes recent techniques applied to characterize surfactant systems, such as surfactant-stabilized colloids, micelles, microemulsions, emulsions and foams in both aqueous and nonaqueous fluids. The text probes adsorption and wetting phenomena at interfaces, including solid-liquid, liquid-vapour and liquid-liquid.

The book is an elaboration upon the material covered in the SPIE short course "The Design of Plastic Optical Systems." It is meant to provide an overview of the design of plastic optical systems and is structured along the lines of a typical development project.

composites and inorganic materials to enhance the optical properties of polymer systems. As aforementioned, the optical properties of polymers strongly depend on the preparation conditions, as shown in Table ent preparation methods of MEH-PPV yield different values of E d[62, 64, ].

In addition, the thermal history also. gives a comprehensive view of characterization and applications of electrical and optical polymers, including fundamentals, methods and applications.

Different chapters are focused on state-of-the-eart applications, with tutorial chapters on electrical and optical polymers, with emphasis on commercial polymers."Cited by: Polymer materials are nowadays used not only in the design of consumer but also of precise optical systems and devices [1].

Their refractometric and disper-sive characteristics as well as some physical, mechanical and thermal properties are essential in the design and production of optical elements. Optical polymersFile Size: KB. • The most common techniques are Differential scanning calorimetry (DSC), Thermal gravimetry (TG), Dynamic mechanical analysis (DMA).

• Used to identify and characterize both polymers and drug-loaded polymeric delivery systems. 58 Optical tweezer guys are crowing about measuring forces in the pN = N range – this corresponds to a mass of about kg = g.

Not even close. And this is a big polymer. Consider the size, then. We know that the size is of the order of the RMS end-to-end distance.

That is given, for a random coil polymer, by r = N ½ l. Preface The Handbook of Optical Materials is a compilation of the physical properties of optical materials used in optical systems and lasers. It contains extensive data tabulations but with a minimum of narration, in a style similar to that of the CRC Handbook of Chemistry and Physics.

The Garland Science website is no longer available to access and you have been automatically redirected to INSTRUCTORS. All instructor resources (*see Exceptions) are now available on our Instructor instructor credentials will not grant access to the Hub, but existing and new users may request access student.

Polymer characterization is the analytical branch of polymer science. The discipline is concerned with the characterization of polymeric materials on a variety of levels. The characterization typically has as a goal to improve the performance of the material.

The book deals with the modelling of steady state and non-steady state basic processes of fibre formation and fibre processing. Focal points are melt spinning processes (polymers and glass, drawing, spunbonded nonwoven), spun yarn spinning processes (drafting, carding) and the description of the dynamics in different process steps during the fibre processing (fibre.

Recent advances in the development of low-loss optical fibers have revolutionized the field of telecommunications, and fiber-based networks form a key part of international communications systems.

This book introduces the physical principles of optical fibers, and details their use in sensor technology and modern optical communication systems/5(2).Polymer optical fibers (POFs) doped with organic dyes can be used to make efficient lasers and amplifiers due to the high gains achievable in short distances.

This paper analyzes the peculiarities of light amplification in POFs through some experimental data and a computational model capable of carrying out both power and spectral analyses.the arrangement of polymer molecules within a bulk polymer material, and techniques used to give information about structure or properties of polymers.

The subjects are logically combined because understanding how structure a ects properties, as measured in characterization, is a key element of polymer materials science and Size: KB.