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|a UAMI
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|a Tiwari, Ashutosh.
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|a Handbook of Graphene Materials.
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|a Newark :
|b John Wiley & Sons, Incorporated,
|c 2019.
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|c ©2019
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|a 1 online resource (344 pages)
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|a text
|b txt
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|a computer
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|a online resource
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|a Cover -- Title Page -- Copyright Page -- Contents -- Preface -- 1 Biological, Biomedical, and Medical Applications of Graphene and Graphene-Based Materials (G-bMs) -- 1.1 Introduction -- 1.2 Advent of Graphene -- 1.3 Importance of Graphene -- 1.4 Biological Applications of Graphene and G-bMs -- 1.4.1 Biosensing and Bioimaging -- 1.4.2 Biotargeting -- 1.4.3 Biomarking and Biorecognition -- 1.5 Medical and Biomedical Applications of Graphene and G-bMs -- 1.5.1 Drug Delivery Applications of Graphene and G-bMs -- 1.5.2 Antibacterial Applications of Graphene and G-bMs -- 1.6 Challenges and Future Trend -- 1.7 Conclusion -- References -- 2 Effect of Graphene Oxide Nanosheets on the Structure and Properties of Cement Composites -- 2.1 Introduction -- 2.2 Preparation and Structural Characteristics of GO Nanosheets -- 2.2.1 Preparation of GO Nanosheets -- 2.2.2 Structural Characteristics of GO Nanosheets -- 2.3 Preparation of Cement Composites with GO Nanosheets -- 2.4 Effect of GO Nanosheets on the Microstructure and Performances of Cement Composites -- 2.4.1 Effects of GO Nanosheet Dosages on the Microstructure and Performances of Cement Composites -- 2.4.2 Effect of GO Nanosheets with Different Oxygen Contents on the Microstructure and Performances of Cement Composites -- 2.4.3 Effect of Hydration Times on the Microstructure and Mechanical Properties of Cement Composites -- 2.4.4 Effect of GO Nanosheet Size on the Microstructure and Mechanical Properties of Cement Composites -- 2.4.5 Effect of GO Nanosheets on the Pore Structure of Hardened Cement Paste -- 2.5 Preparation of Cement Composites with Large-Scale Ordered Microstructures by Doping Few-Sheet GO Nanosheets and Investigation of Their Structure and Performance -- 2.5.1 Preparation of Few-Sheet GO Nanosheets by Forming CCS/GO Intercalation Composites.
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|a 2.5.2 Preparation of Large-Scale and Large-Volume Ordered Structural Cement Composites -- 2.5.3 Mechanical Properties and Durability Parameters of Cement Composites -- 2.6 Effect of GO Nanosheets on the Crystal Structure of Cement Hydration Crystals -- 2.7 Formation Mechanism of Regular-Shaped Cement Hydration Crystals and Ordered Microstructure -- 2.7.1 Regulation Mechanism of GO Nanosheets on Cement Hydration Products -- 2.7.2 Forming Mechanism of Large-Scale Regular Hydration Crystals and Large-Volume Ordered Microstructure of Cement Composites -- 2.7.3 Experiment Base of the Forming Mechanism of Regular Cement Composites -- 2.8 Conclusion and Future Trends -- References -- 3 Adaptation and Viability of Graphene-Based Materials in Clinical Improvement -- 3.1 Introduction -- 3.2 Biomedical Properties of Graphene -- 3.3 Optical and Biological Properties of Graphene -- 3.4 Safety and Sustainability of Graphene in Medical Application -- 3.5 Laboratory Preparation of Graphene -- 3.6 Graphene-Based Materials and Its Risk Index -- 3.7 Applications of Graphene-Based Materials in Clinical Improvement -- 3.7.1 Tissue Engineering -- 3.7.2 Modified Graphene Material in Gene Delivery -- 3.7.3 Drug Delivery -- 3.8 Combination of Graphene in Polymer-Based Composites for Improved Bioactivities -- 3.9 Application of Graphene in Metal-Matrix Formation for Biomedical Applications -- 3.10 Conclusion and Future Outlook -- Acknowledgments -- References -- 4 Graphene-Based Synaptic Devices for Neuromorphic Applications -- 4.1 Basics of Neuromorphic Computing -- 4.1.1 Demand for Devices for Neuromorphic Applications -- 4.1.2 Basics of Biological Synapse -- 4.1.3 Basic Work Principle of Synaptic Devices -- 4.1.3.1 RRAM Used as Synaptic Device -- 4.1.3.2 Transistor Used as Synaptic Device -- 4.2 Introduction of Graphene.
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|a 4.3 Graphene Used as the Inserted Layer in RRAM Devices -- 4.3.1 Reasons for Choosing Graphene as the Inserted Layer in RRAM -- 4.3.2 Device Structure Comparison -- 4.3.3 Device Fabrication -- 4.3.4 Use of Graphene -- 4.3.4.1 Monitoring Oxygen Movement by Raman Spectrum -- 4.4 Graphene Used as the Electrode in RRAM Devices -- 4.4.1 Reasons for Choosing Graphene as an Electrode in RRAM -- 4.4.1.1 Flexible Electrode -- 4.4.1.2 Feasibility for Large-Scale Production -- 4.4.1.3 Gate Tunability -- 4.4.1.4 Ability to Catch Oxygen Ions -- 4.4.2 Graphene-Based Fin Structure RRAM -- 4.4.2.1 Advantages of Fin Structure -- 4.4.2.2 LSG-The Approach to Form Fin-Like Structure -- 4.4.2.3 Device Fabrication Process -- 4.4.2.4 Electrical Properties -- 4.4.2.5 Mechanism of the Device -- 4.4.2.6 Future Prospect -- 4.4.3 Gate-Controlled BLG-Electrode RRAM -- 4.4.3.1 Reasons for Using Gate-Controlled RRAM -- 4.4.3.2 Device Fabrication Process -- 4.4.3.3 Electrical Properties -- 4.4.3.4 Mechanism of This Device -- 4.4.3.5 Future Prospect -- 4.5 From RRAM to Synaptic Device -- 4.5.1 Dual Mode in BLG-Based Artificial Synaptic Device -- 4.5.1.1 Inhibitory Synaptic Device: The Way to Mimic the "Learning" Process -- 4.5.1.2 Device Fabrication -- 4.5.1.3 Electrical Properties and Mechanism -- 4.5.1.4 Further Prospect -- 4.5.2 Graphene Dynamic Synapse with Modulatable Plasticity -- 4.5.2.1 Modulatable Plasticity -- 4.5.2.2 Device Structure and Fabrication -- 4.5.2.3 Hysteresis and Its Origin -- 4.5.2.4 Reason for Using Twisted BLG -- 4.5.2.5 Electrical Properties -- 4.5.2.6 Future Prospect -- 4.6 Prospect -- 4.7 Conclusion -- References -- 5 Graphene-Based Materials for Implants -- 5.1 Introduction -- 5.2 Graphene-Based Materials -- 5.2.1 Synthesis and Properties -- 5.2.1.1 Graphene Oxide (GO) -- 5.2.1.2 Reduced GO (rGO) -- 5.2.1.3 Graphene Nanomaterials.
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|a 5.2.2 Applications of GBMs -- 5.2.3 Implants -- 5.2.3.1 Orthopedic Implants -- 5.2.3.2 Dental Implants -- 5.2.3.3 Drug Delivery Implants -- 5.2.3.4 Biosensor Implants -- 5.2.4 Biodegradation and Elimination -- 5.2.5 Toxicity -- 5.3 Conclusion -- Acknowledgments -- References -- 6 Ultrashort Pulse Fiber Laser Generation Using Molybdenum Disulfide and Tungsten Disulfide Saturable Absorber -- 6.1 Introduction -- 6.2 Background of Fiber Laser -- 6.3 Mode-Locked Fiber Laser -- 6.3.1 Saturable Absorber -- 6.4 Transition Metal Dichalcogenides -- 6.4.1 Tungsten Disulfide -- 6.4.2 Molybdenum Disulfide -- 6.5 Fabrication and Characterization of SA -- 6.6 Fiber Laser Configuration -- 6.7 Performance of Ultrashort Laser with WS2 SA -- 6.8 Performance of Ultrashort Laser with MoS2 SA -- 6.9 Summary -- References -- 7 Graphene-Modified Asphalt -- 7.1 Introduction -- 7.2 Molecular Simulations and Experiments -- 7.2.1 GMA and the Interfacial Model of Graphene and Asphalt -- 7.2.2 Thermomechanical Properties of GMA -- 7.2.2.1 Thermal Expansion Coefficient Calculation -- 7.2.2.2 Thermal Conductivity Calculation -- 7.2.2.3 Shear Modulus Calculation -- 7.2.2.4 Elastic Constants and Modulus Calculation -- 7.2.2.5 Glass Transition Temperature and Thermal Properties -- 7.2.3 Interfacial Behavior of Graphene and Asphalt -- 7.2.3.1 Interface Mechanical Behavior -- 7.2.3.2 Interface Energy Calculation -- 7.2.3.3 Interface Interaction -- 7.2.3.4 Interface Failure Modes -- 7.2.4 Self-Healing Properties of GMA and Mortar -- 7.2.4.1 Reaction Energy Barrier of Self-Healing -- 7.2.4.2 Healing Index -- 7.2.4.3 Self-Healing Properties -- 7.2.4.4 Self-Healing Time -- 7.3 Conclusion -- Acknowledgments -- References -- 8 Graphene-Based Materials for Brain Targeting -- 8.1 Introduction -- 8.2 Graphene-Based Biomaterials -- 8.3 Drug Delivery to the Brain.
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|a 8.3.1 Route of Transportation of Drug Across the BBB -- 8.3.1.1 Paracellular Transport Route in Brain-Diseased State -- 8.3.1.2 Transcellular Transport Route in Brain-Diseased State -- 8.3.1.3 Mode of Transport Across the Brain -- 8.4 Graphene-Based Drug Delivery Systems -- 8.4.1 Graphene-Based Drug Delivery Systems for the Treatment of Brain Cancer -- 8.4.2 Graphene-Based Systems for Diagnostic Application and Drug Delivery for the Treatment of AD -- 8.4.3 Graphene-Based Drug Delivery Systems for the Treatment of Subarachnoid Hemorrhage -- 8.4.4 Graphene-Based Materials for Neural Regeneration -- 8.4.5 Graphene-Based Materials for the Treatment of Stroke -- 8.4.6 Graphene-Based Materials for the Treatment of Parkinson's Disease -- 8.4.7 Graphene-Based Materials for the Treatment of Epilepsy -- 8.4.8 Graphene-Based Materials for Treatment of Multiple Sclerosis -- 8.5 Conclusion -- Acknowledgments -- References -- 9 Antimicrobial Activities of Graphene-Based Materials -- 9.1 Introduction -- 9.2 Antimicrobial Activities of BGMs -- 9.2.1 Antibacterial Activities -- 9.2.2 Antifungal Activities -- 9.2.3 Antiviral Activities -- 9.3 Toxicological Effect of GBMs -- 9.4 Conclusion -- Acknowledgments -- References -- 10 Graphene Quantum Dots-A New Member of the Graphene Family: Structure, Properties, and Biomedical Applications -- 10.1 Structure of Graphene Quantum Dots -- 10.2 Synthesis of GQDs -- 10.2.1 Bottom-Up Synthetic Approaches -- 10.2.2 Top-Down Synthetic Approaches -- 10.3 Morphological and Optical Properties -- 10.4 Applications -- 10.5 Biological Properties of GQDs -- 10.5.1 Cytotoxicity -- 10.5.2 GQD in Biosensing -- 10.5.2.1 Photoluminescencent GQD Biosensors -- 10.5.2.2 Electrochemical GQD Biosensors -- 10.5.2.3 Electrochemiluminescence Biosensor Based on GQD -- 10.5.3 GQD as an Agent in Bioimaging.
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|a 10.5.4 GQD as an Agent in Photodynamic Therapy.
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|a Publisher supplied metadata and other sources
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| 590 |
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|a ProQuest Ebook Central
|b Ebook Central Academic Complete
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| 650 |
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|a Biomedical materials.
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| 650 |
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|a Biomatériaux.
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| 650 |
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|a Biomedical materials
|2 fast
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| 700 |
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|a Harun, Sulaiman Wadi.
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| 758 |
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|i has work:
|a Handbook of Graphene Materials (Text)
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|i Print version:
|a Tiwari, Ashutosh.
|t Handbook of Graphene Materials.
|d Newark : John Wiley & Sons, Incorporated, ©2019
|z 9781119469773
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| 856 |
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