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碳材料科学与工程:表征

碳材料科学与工程:表征

作者:稻垣道夫
出版社:清华大学出版社出版时间:2017-06-01
开本: 32开 页数: 318
读者评分:5分1条评论
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碳材料科学与工程:表征 版权信息

碳材料科学与工程:表征 本书特色

碳材料由于其结构多样性,导致其性能多样化,因而应用领域广阔,碳材料研究已受到全球材料科学界、物理学界、化学界的广泛关注。本书系统介绍了碳材料表征技术及应用,包括 X射线粉末衍射、小角X射线散射、透射电镜、扫描电子显微镜、图像分析、拉曼光谱、X射线光电子能谱、磁电阻、电化学性能、气体吸附/解吸等温线、热分析、表面官能团滴定测定、程序升温脱附技术。本书读者对象为材料领域的科技人员、研究生和高校教师。本书以英文著述,并与 Elsevier出版集团合作已在海外出版。

碳材料科学与工程:表征 内容简介

碳材料由于其结构多样性,导致其性能多样化,因而应用领域广阔,碳材料研究已受到全球材料科学界、物理学界、化学界的广泛关注。本书系统介绍了碳材料表征技术及应用。包括X射线粉末衍射、小角X射线散射、透射电镜、扫描电子显微镜、图像分析、拉曼光谱、X射线光电子能谱、磁电阻、电化学性能、气体吸附/解吸等温线、热分析、表面官能团滴定测定、程序升温脱附技术。本书读者对象为材料领域的科技人员、研究生和高校教师。本书以英文著述,并与Elsevier出版集团合作,已在海外出版。

碳材料科学与工程:表征 目录

List of Contributors................................................................................. Preface ............................................................................................... Acknowledgments ................................................................................ CHAPTER 1 Introduction............................................................ 1 Michio Inagaki, Feiyu Kang 1.1 Carbon Materials............................................................... 1 1.2 Characterization of Carbon Materials.................................... 3 1.3 Structure of the Present Book.............................................. 5 References.............................................................................. 6 CHAPTER 2 X-ray Powder Diffraction ......................................... 7 Norio Iwashita 2.1 Introduction...................................................................... 7 2.2 X-ray Diffraction Pattern of Carbon Materials........................ 8 2.3 Parameters Determined by X-ray Diffraction.........................10 2.4 Instrumentation ................................................................11 2.5 Specifications for Measurement ..........................................14 2.5.1 Preparation of Sample for X-ray Measurements............ 14 2.5.2 Measurement and Intensity Correction of Diffraction Profiles.................................................................. 14 2.5.3 Correction of Diffraction Angle With Internal Standard ................................................................ 16 2.5.4 Determination of Full Width at Half Maximum Intensity ................................................................ 17 2.5.5 Accuracy of the Values Determined............................ 18 2.6 Degree of Graphitization ...................................................18 2.7 Key Issues for Measurement...............................................21 2.7.1 Diffraction Pattern................................................... 21 2.7.2 Use of Internal Standard........................................... 21 2.7.3 Use of Thin Sample Holder....................................... 22 2.7.4 Indexing the Diffraction Line .................................... 23 2.7.5 Separation into Component Profiles............................ 23 2.8 Concluding Remarks.........................................................24 References.............................................................................24 CHAPTER 3 Small-Angle X-ray Scattering..................................27 Katsuya Fukuyama, Yoshikiyo Hatakeyama 3.1 Introduction.....................................................................27 3.2 Fundamentals ..................................................................28 3.3 Key Issues for the Measurements ........................................33 3.4 Applications for Carbon Materials.......................................35 3.4.1 Porous Carbon Fibers............................................... 35 3.4.2 Glass-Like Carbons ................................................. 36 3.4.3 Mesocellular Foam Carbons (Silica-Templated Carbons)................................................................ 38 3.4.4 Open Pores Formed by Air Oxidation......................... 40 3.5 Concluding Remarks.........................................................42 References.............................................................................42 CHAPTER 4 Transmission Electron Microscopy..........................45 Sylvie Bonnamy, Agne`s Oberlin 4.1 Introduction.....................................................................45 4.2 Modes of Transmission Electron Microscopy ........................46 4.2.1 Diffracting Mode..................................................... 47 4.2.2 Imaging Modes....................................................... 47 4.3 Key Issues for Observation ................................................48 4.3.1 Object Thickness (Weak Phase Object) ....................... 48 4.3.2 Contrast Transfer Function of the Transmission Electron Microscope................................................ 49 4.3.3 Diffusion Contrasts.................................................. 54 4.3.4 Fresnel Fringes, ie, Edge Fringes ............................... 54 4.5 Applications for Carbon Materials.......................................56 4.5.1 Transmission Electron Microscopy Modes to Study Crystallinity of Carbon Materials ............................... 56 4.5.2 Transmission Electron Microscopy Modes in the Study of Carbonization and Graphitization ............. 62 4.6 Conclusions.....................................................................69 References.............................................................................69 Further Reading......................................................................70 CHAPTER 5 Scanning Electron Microscopy ...............................71 Akira Yoshida, Yutaka Kaburagi, Yoshihiro Hishiyama 5.1 Introduction.....................................................................71 5.2 Instrumentation and Resolving Power ..................................72 5.2.1 Instrumentation....................................................... 73 5.2.2 Magnification and Resolving Power of the Scanning Electron Microscope................................... 75 5.2.3 Edge Effects Appearing in SE Mode Images................ 76 5.3 Specimen Preparation........................................................77 5.4 Observation With the Out-Lens Objective Lens System ..........79 5.5 Observation With the Snorkel Objective Lens System.............81 5.6 Observation With the In-Lens System..................................82 5.7 Electron Channeling Effect ................................................83 5.7.1 Electron Channeling Effect for Kish Graphite .............. 83 5.7.2 Electron Channeling Pattern for Kish Graphite and HOPG Specimens.............................................. 86 5.7.3 Mapping and Crystal Grain Size Evaluation................. 88 5.8 Concluding Remarks.........................................................91 References.............................................................................92 CHAPTER 6 Image Analysis ......................................................95 Kyoichi Oshida 6.1 Introduction.....................................................................95 6.2 Image Analysis Methods ...................................................96 6.2.1 Process of Image Analysis ........................................ 96 6.2.2 Analysis of Space Frequency..................................... 97 6.2.3 Three-Dimensional Transmission Electron Microscopy ...........................................................100 6.2.4 Software for the Analysis ........................................100 6.3 Structure Analysis Through Transmission Electron Microscopy ................................................................... 101 6.3.1 Cup-Stacked Type Carbon Nanotubes ........................101 6.3.2 Carbon Nanotubes Loaded With Metal Particles ..........104 6.3.3 Thin Graphite ........................................................108 6.3.4 Disordered Carbon .................................................108 6.4 Texture Analysis Through Scanning Electron Micrographs .................................................................. 113 6.5 Texture Analysis Through Optical Micrographs................... 116 6.6 Concluding Remarks....................................................... 120 References........................................................................... 121 CHAPTER 7 Raman Spectroscopy............................................ 125 Yutaka Kaburagi, Akira Yoshida, Yoshihiro Hishiyama 7.1 Introduction................................................................... 126 7.2 Fundamentals ................................................................ 126 7.3 Key Issues for the Measurements ...................................... 129 7.3.1 Laser Probe Sampling Depth....................................129 7.3.2 Polarization of Laser Light ......................................129 7.3.3 Sampling Area.......................................................131 7.3.4 Temperature ..........................................................132 7.3.5 Elimination of Background Intensity .........................132 7.3.6 Excitation Energy Dependence of D Band..................133 7.3.7 Calibration of Raman Frequency...............................134 7.3.8 Equipment ............................................................136 7.4 As a Measure for Structure Characterization ....................... 138 7.4.1 G Band.................................................................138 7.4.2 D and D0 Bands .....................................................141 7.5 Concluding Remarks....................................................... 149 References........................................................................... 150 CHAPTER 8 X-ray Photoelectron Spectroscopy ........................ 153 Hidetaka Konno 8.1 Introduction................................................................... 153 8.2 Practical Side of Measurements ........................................ 154 8.3 State Analysis................................................................ 156 8.3.1 Determination of Binding Energy..............................156 8.3.2 Background Subtraction ..........................................158 8.3.3 Peak Separation .....................................................159 8.3.4 State Analysis Using Chemical Shift .........................164 8.4 Semiquantitative Analysis................................................ 166 8.5 Concluding Remarks....................................................... 168 References........................................................................... 169 CHAPTER 9 Magnetoresistance............................................... 173 Yoshihiro Hishiyama, Yutaka Kaburagi, Michio Inagaki 9.1 Introduction................................................................... 174 9.2 General Scheme of Dr/r0 Change With Graphitization ......... 174 9.3 Measurement of Magnetoresistance ................................... 178 9.3.1 Specimen Shape.....................................................178 9.3.2 Magnetic Field Orientation Schemes .........................179 9.3.3 Instruments ...........................................................182 9.4 Magnetoresistance Parameters for Coke ............................. 185 9.4.1 Coke B and Gilsonite Coke......................................185 9.4.2 Coke Prepared From Hydrogenated Ethylene Tar Pitch...............................................................186 9.5 Magnetoresistance Parameters for Carbon Fibers and Extruded Coke......................................................... 189 9.5.1 Benzene-Derived Vapor-Grown Carbon Fiber and Extruded Coke.................................................189 9.5.2 Other Carbon Fibers ...............................................191 9.6 Magnetoresistance Parameters for Highly Crystallized Graphite Materials.......................................................... 192 9.7 Concluding Remarks....................................................... 194 Supplement: Background of the Characterization of Carbon Materials With Dr/r0 ............................................................ 195 S-1 Origin of the Sign of Dr/r0............................................... 195 S-2 Microtexture .................................................................. 197 S-3 Relationship Between Microtexture and Magnetoresistance.... 199 References........................................................................... 203 CHAPTER 10 Electrochemical Performance............................. 205 Soshi Shiraishi 10.1 Introduction................................................................. 205 10.2 Fundamentals............................................................... 206 10.2.1 Capacitance .......................................................206 10.2.2 Construction of Measurement Cell.........................208 10.2.3 Electrochemically Analytical Mode .......................209 10.2.4 Differential Capacitance and Integral Capacitance .......................................................211 10.2.5 Definition of Specific Capacitance.........................212 10.3 Measurement Procedure................................................. 214 10.3.1 Measurement Cell...............................................214 10.3.2 Preparation of Carbon Electrode............................216 10.3.3 Aqueous Acid Electrolyte System (by Three-Electrode Cell).....................................218 10.3.4 Organic Electrolyte System (by Three-Electrode Cell).....................................219 10.3.5 Organic Electrolyte System (by Two-Electrode Cell) ......................................221 10.4 Concluding Remarks..................................................... 224 References........................................................................... 224 CHAPTER 11 Gas Adsorption/Desorption Isotherm for Pore Structure Characterization..................... 227 Yoko Nishi, Michio Inagaki 11.1 Introduction................................................................. 228 11.2 Fundamentals............................................................... 229 11.3 Key Issues for the Measurements and Analyses ................. 232 11.3.1 Sample Amount for the Measurement ....................232 11.3.2 Pretreatment of Sample........................................232 11.3.3 BrunauereEmmetteTeller Method ........................233 11.3.4 as Plot ..............................................................234 11.3.5 BarretteJoynereHalenda Method..........................235 11.3.6 DubinineRadushkevich Method............................237 11.3.7 Density Functional Theory Method........................238 11.4 Application to Carbon Materials ..................................... 239 11.4.1 Microporous Carbons ..........................................239 11.4.2 Mesoporous Carbons...........................................241 11.4.3 Measurements Using Various Gases as Adsorbate ....243 11.4.4 Gravimetric Measurement of Adsorption/ Desorption of CO2 ..............................................244 11.5 Concluding Remarks..................................................... 245 References........................................................................... 246 CHAPTER 12 Thermal Analysis ............................................... 249 Ming-ming Chen 12.1 Introduction................................................................. 249 12.2 Fundamentals in Thermal Analyses ................................. 250 12.3 Key Issues for the Measurements .................................... 252 12.4 Applications of TG and DTG for Carbon Materials ............ 256 12.4.1 Biomasses .........................................................256 12.4.2 Pitches..............................................................258 12.4.3 Organic Polymers ...............................................258 12.4.4 Measurements in Oxygen.....................................263 12.5 Applications of DTA and DSC for Carbon Materials .......... 265 12.5.1 Pitches..............................................................265 12.5.2 Organic Polymers ...............................................267 12.5.3 Intercalation Reactions ........................................269 12.6 Concluding Remarks..................................................... 269 References........................................................................... 270 CHAPTER 13 Titration Method for the Identification of Surface Functional Groups.............................. 273 Yern Seung Kim, Chong Rae Park 13.1 Introduction................................................................. 273 13.2 Basic Concept of Titration Method.................................. 276 13.3 Instrumentation ............................................................ 279 13.4 Specification for the Methodology................................... 279 13.4.1 Reaction Step.....................................................280 13.4.2 Filtration Step ....................................................281 13.4.3 Titration Step.....................................................281 13.5 Analysis of the Titration Results ..................................... 281 13.6 Key Points for the Titration Measurements ....................... 284 13.6.1 Preparation of the Reaction Mixture for the Reaction Step..................................................................284 13.6.2 Agitation Method and Period................................284 13.6.3 Titration Condition and End Point Determination.....285 13.7 Concluding Remarks..................................................... 285 References........................................................................... 285 CHAPTER 14 Temperature Programmed Desorption.................. 287 Takafumi Ishii, Takashi Kyotani 14.1 Introduction................................................................. 287 14.2 TPD Experimental Conditions and Apparatus.................... 288 14.3 Assignment of TPD Peaks to Surface Functional Groups........................................................................ 291 14.4 Secondary Reactions During a TPD Run .......................... 296 14.5 Effect of Air Exposure on TPD Patterns ........................... 299 14.6 Effect of Inorganic Matter in Carbons.............................. 300 14.7 Concluding Remarks..................................................... 302 References........................................................................... 302 Index...................................................................................................307
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碳材料科学与工程:表征 作者简介

Michio Inagaki教授,日本北海道大学荣休教授。担任过日本碳素学会主席,JSPS117委员会主席,Carbon杂志副主编。获得过美国和中国碳素学会、日本陶瓷学会学术贡献奖。出版8本书,发表700多篇学术论文。Feiyu Kang(康飞宇),教授,清华大学深圳研究生院院长。现任SCI刊物《Carbon》顾问编委,SCI刊物《新型炭材料》副主编,层间化合物系列国际会议(ISIC)国际顾问委员会委员。曾获国家发明奖等多项奖励。出版中英文专著5部,在国内外发表论文200多篇。

商品评论(1条)
  • 主题:表征方法全面

    如果研究碳材料的话,还是建议好好看看这本书,虽然细分材料没有详尽介绍,但是已经足够了,还有探索空间。

    2018/8/31 16:25:59
    读者:201***(购买过本书)
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