| Edition |
2nd ed. |
| Description |
1 online resource (xi, 539 pages) : illustrations |
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text txt rdacontent |
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computer c rdamedia |
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online resource cr rdacarrier |
| Note |
Print version record. |
| Bibliography |
Includes bibliographical references and index. |
| Summary |
Annotation Materials Science and Engineering of Carbon: Fundamentals provides a comprehensive introduction to carbon, the fourth most abundant element in the universe. The contents are organized into two main parts. Following a brief introduction on the history of carbon materials, Part 1 focuses on the fundamental science on the preparation and characterization of various carbon materials, and Part 2 concentrates on their engineering and applications, including hot areas like energy storage and environmental remediation. The book also includes up-to-date advanced information on such newer carbon-based materials as carbon nanotubes and nanofibers, fullerenes and graphenes. Through review on fundamental science, engineering and applications of carbon materials. Overview on a wide variety of carbon materials (diamond, graphite, fullerene, carbon nanotubes, graphene, etc.) based on structure and nanotexture. Description on the preparation and applications of various carbon materials, in the relation to their basic structure and properties. |
| Contents |
Front Cover; Materials Science and Engineering of Carbon; Copyright Page; Contents; Preface; Acknowledgments; 1 Introduction; 1.1 Carbon materials; 1.2 Short history of carbon materials; 1.3 Classic carbons, new carbons, and nanocarbons; 1.3.1 Classic carbons; 1.3.2 New carbons; 1.3.3 Nanocarbons; 1.4 Construction and purposes of the present book; References; 2 Fundamental Science of Carbon Materials; 2.1 Carbon families; 2.1.1 Carbon-carbon bonds; 2.1.2 Carbon families; 2.1.3 Structural relation to neighboring atoms; 2.2 Structure and texture of carbon materials; 2.2.1 Structure. |
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2.2.2 Structure development with heat treatment (carbonization and graphitization)2.2.3 Nanotexture; 2.2.4 Microtexture (agglomeration); 2.3 Carbonization (nanotexture development); 2.3.1 Formation processes of carbon materials; 2.3.2 Gas phase carbonization; a Carbon blacks; b Pyrolytic carbons; c Vapor-grown carbon fibers and nanofibers; d Carbon nanotubes; e Fullerenes; f Graphenes; 2.3.3 Solid phase carbonization; a Activated carbons; b Glass-like carbons; c Carbon fibers; d Carbon films derived from aromatic polyimides; 2.3.4 Liquid phase carbonization; a Mesophase in pitches. |
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B Mesophase spheresc Bulk mesophase; d Control of optical texture of bulk mesophase; e Fractionation of pitches; 2.4 Novel techniques for carbonization; 2.4.1 Template method; 2.4.2 Polymer blend method; 2.4.3 Electrospinning; 2.4.4 Pressure carbonization; 2.4.5 High-yield carbonization; 2.4.6 Low-temperature carbonization; 2.5 Graphitization (structure development); 2.5.1 Structure parameters; 2.5.2 Graphitization behavior; a Carbon materials with planar orientation; b Carbon materials with axial orientation; c Carbon materials with point orientation. |
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D Carbon materials with random orientation2.5.3 Relations among structure parameters; 2.5.4 Graphitization process; 2.5.5 Graphitizing and non-graphitizing carbons; 2.5.6 Heterogeneous graphitization (multiphase graphitization); 2.6 Acceleration of graphitization; 2.6.1 Catalytic graphitization; 2.6.2 Stress graphitization; 2.6.3 Graphitization of exfoliated carbon fibers; 2.7 Pore development in carbon materials; 2.7.1 Pores in carbon materials; 2.7.2 Identification of pores; a Scanning tunneling microscopy; b Transmission electron microscopy; c Gas adsorption; d Scanning electron microscopy. |
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E Optical microscopyf Liquid impregnation; 2.7.3 Pore development in carbon materials; a Development of extrinsic nano-sized pores in glass-like carbons; b Macropore development in exfoliated graphite; c Development of extrinsic pores in graphite intercalation compounds; 2.8 Introduction of foreign species; 2.8.1 Possibility to introduce foreign species into carbon materials; 2.8.2 Intercalation; a Characteristics of intercalation compounds; b Synthesis of intercalation compounds; 2.8.3 Substitution; a Substitution for carbon atoms; b Substitution of B; c Substitution of N; 2.8.4 Doping. |
| Subject |
Materials science.
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Carbon compounds.
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Science des matériaux.
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Carbone -- Composés.
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TECHNOLOGY & ENGINEERING -- Engineering (General)
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TECHNOLOGY & ENGINEERING -- Reference.
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Carbon compounds
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Materials science
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| Genre/Form |
Electronic book.
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Electronic books.
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| Added Author |
Kang, Feiyu.
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| Other Form: |
Print version: Inagaki, Michio. Materials science and engineering of carbon. 2nd ed. Waltham, MA : Butterworth-Heinemann, 2014 9780128011522 (OCoLC)881570866 |
| ISBN |
9780128011522 |
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0128011521 |
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012800858X |
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9780128008584 |
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9780128008584 |
| Standard No. |
AU@ 000053331024 |
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AU@ 000061145145 |
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CHBIS 010295342 |
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CHNEW 001012355 |
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CHVBK 327782420 |
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DEBBG BV042182157 |
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DEBBG BV042309794 |
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DEBSZ 414276256 |
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DEBSZ 417228333 |
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DEBSZ 43170161X |
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GBVCP 882732099 |
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