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Full Description
The expansion of carbon materials is multidisciplinary and is related to physics, chemistry, biology, applied sciences and engineering. The research on carbon materials has mostly focused on aspects of fundamental physics as they unique electrical, thermal and mechanical properties applicable for the range of applications. The electrons in graphene and other derived carbon materials behave as dirac fermions due to their interaction with the ions of the lattice. This direction has led to the discovery of new phenomena such as Klein tunneling in carbon based solid state systems and the so-called half-integer quantum Hall effect. Advanced Carbon Materials and Technology presents cutting-edge chapters on the processing, properties and technological developments of graphene, carbon nanotubes, carbon fibers, carbon particles and other carbon based structures including multifunctional graphene sheets, graphene quantum dots, bulky balls, carbon balls, and their polymer composites.
This book brings together respected international scholars writing on the innovative methodologies and strategies adopted in carbon materials research area including
Synthesis, characterization and functionalization of carbon nanotubes and graphene
Surface modification of graphene
Carbon based nanostructured materials
Graphene and carbon nanotube based electrochemical (bio)sensors for environmental monitoring
Carbon catalysts for hydrogen storage materials
Optical carbon nanoobjects
Graphene and carbon nanotube based biosensors
Carbon doped cryogel films
Bioimpact of carbon nanomaterials
Photocatalytic nature of carbon nanotube based composites
Engineering behavior of ash fills
Fly ash syntactic foams microstructure
Contents
Preface xiii Part 1 Graphene, Carbon Nanotubes and Fullerenes 1
1 Synthesis, Characterization and Functionalization of Carbon Nanotubes and Graphene: A Glimpse of Their Application 3
Mahe Talat and O.N. Srivastava
1.1 Introduction 4
1.2 Synthesis and Characterization of Carbon Nanotubes 5
1.3 Synthesis and Characterization of Graphene 11
1.4 Methods Used in Our Lab: CVD, Thermal Exfoliation, Arc Discharge and Chemical Reduction 14
1.5 Functionalization of Carbon Nanotubes and Graphene 19
1.6 Applications 24
1.7 Conclusion 29
Acknowledgements 29
References 30
2 Surface Modification of Graphene 35
Tapas Kuila, Priyabrata Banerjee and Naresh Chandra Murmu
2.1 Introduction 36
2.2 Surface-Modified Graphene from GO 39
2.3 Application of Surface-Modified Graphene 70
2.4 Conclusions and Future Directions of Research 75
Acknowledgement 77
References 77
3 Graphene and Carbon Nanotube-based Electrochemical Biosensors for Environmental Monitoring 87
G. Alarcon-Angeles, G.A. Álvarez-Romero and A. Merkoçi
3.1 Introduction 88
3.2 Applications of Electrochemical Biosensors 97
3.3 Conclusions and Future Perspectives 121
References 121
4 Catalytic Application of Carbon-based Nanostructured Materials on Hydrogen Sorption Behavior of Light Metal Hydrides 129
Rohit R Shahi and O.N. Srivastava
4.1 Introduction 130
4.2 Different Carbon Allotropes 133
4.3 Carbon Nanomaterials as Catalyst for Different Storage Materials 135
4.4 Key Results with MgH2, NaAlH4 and Li-Mg-N-H Systems 137
4.5 Summary 164
Acknowledgements 165
References 165
5 Carbon Nanotubes and Their Applications 173
Mohan Raja and J. Subha
5.1 Introduction 173
5.2 Carbon Nanotubes Structure 174
5.3 Carbon Nanotube Physical Properties 176
5.4 Carbon Nanotube Synthesis and Processing 177
5.5 Carbon Nanotube Surface Modification 178
5.6 Applications of Carbon Nanotubes 179
5.7 Conclusion 187
References 187
6 Bioimpact of Carbon Nanomaterials 193
A. Djordjevic, R. Injac, D. Jovic, J. Mrdjanovic and M. Seke
6.1 Biologically Active Fullerene Derivatives 194
6.2 Biologically Active Graphene Materials 219
6.3 Bioimpact of Carbon Nanotubes 230
6.4 Genotoxicity of Carbon Nanomaterials 238
6.5 Ecotoxicological Effects of Carbon Nanomaterials 247
References 251
Part 2 Composite Materials 273
7 Advanced Optical Materials Modified with Carbon Nano-Objects 275
Natalia V. Kamanina
7.1 Introduction 275
7.2 Photorefractive Features of the Organic Materials with Carbon Nanoparticles 279
7.3 Homeotropic Alignment of the Nematic Liquid Crystals Using Carbon Nanotubes 297
7.4 Thin Film Polarization Elements and Their Nanostructurization via CNTs 303
7.5 Spectral and Mechanical Properties of the Inorganic Materials via CNTs Application 307
7.6 Conclusion 310
Acknowledgments 311
References 312
8 Covalent and Non-Covalent Functionalization of Carbon Nanotubes 317
Tawfi k A. Saleh and Vinod K. Gupta
8.1 Introduction 317
8.2 Functionalization of Carbon Nanotubes 318
8.3 Covalent Functionalization 318
8.4 Non-Covalent Functionalization 320
8.5 Functionalization of CNT with Nanoparticles 320
8.6 Conclusion 326
Acknowledgment 327
References 327
9 Metal Matrix Nanocomposites Reinforced with Carbon Nanotubes 331
Praveennath G. Koppad, Vikas Kumar Singh, C.S. Ramesh, Ravikiran G. Koppad and K.T. Kashyap
9.1 Introduction 332
9.2 Carbon Nanotubes 333
9.3 Processing and Microstructural Characterization of Metal Matrix Nanocomposites 338
9.4 Mechanical Properties of Carbon Nanotube Reinforced Metal Matrix Nanocomposites 353
9.5 Strengthening Mechanisms 361
9.6 Thermal Properties of Carbon Nanotube Reinforced Metal Matrix Nanocomposites 363
9.7 Tribological Properties of Carbon Nanotube Reinforced Metal Matrix Nanocomposites 366
9.8 Challenges 368
9.9 Concluding Remarks 371
References 371
Part 3 Fly Ash Engineering and Cryogels 377
10 Aluminum/Fly Ash Syntactic Foams: Synthesis, Microstructure and Properties 379
Dung D. Luong, Nikhil Gupta and Pradeep K. Rohatgi
10.1 Introduction 380
10.2 Hollow Particles 382
10.3 Synthesis Methods 388
10.4 Microstructure of Aluminum/Fly Ash Composites 393
10.5 Properties of Aluminum/Fly Ash Syntactic Foams 398
10.6 Applications 409
10.7 Conclusion 411
Acknowledgments 412
References 412
11 Engineering Behavior of Ash Fills 419
Ashutosh Trivedi
11.1 Background 420
11.2 Engineering Evaluation of Cemented Ash Fill 439
11.3 Problems of Uncemented Ash Fill 446
11.4 Ash as a Structural Fill 453
11.5 Conclusions 470
Salutations, Acknowledgement and Disclaimer 470
References 471
12 Carbon-Doped Cryogel Thin Films Derived from Resorcinol Formaldehyde 475
Z. Markoviæ, D. Kleut, B. Babiæ, I. Holclajtner-Antunoviæ , V. Pavlovicæ and B. Todoroviæ-Markoviæ
12.1 Introduction 476
12.2 Experimental Procedure 476
12.3 Results and Discussion 477
12.4 Conclusion 483
Acknowledgements 484
References 484
Index 487
