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Properties and Functionalization of Graphene

Properties and Functionalization of Graphene
A Computational Chemistry Approach

by Dinadayalane Tandabany,Frank Hagelberg

  • Publisher : Elsevier
  • Release : 2021-09-15
  • Pages : 400
  • ISBN : 9780128195147
  • Language : En, Es, Fr & De
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There has been rapid development in graphene research in recent years due to its outstanding properties and breadth of potential fields it can be applied in, making tools which provide an insight into the properties of functionalized graphene of increasing importance. Properties and Functionalization of Graphene: Computational Chemistry Approaches highlights how computational chemistry can be used to explore the molecular interactions at play in this material, helping researchers model, understand and manipulate the properties of graphene for varied applications. In addition to highlighting current approaches to computational analysis, chapters also discuss the comparison of results and experimental evidence, experimental techniques employed in the functionalization of graphene and challenges associated with these, and the properties of functionalized graphene. Under the guidance of its expert editor, Properties and Functionalization of Graphene: Computational Chemistry Approaches shares the insights of a global team of specialists, making it an authoritative, practical guide for all those studying, developing or applying graphene across a whole range of fields. Provides practical insight into the latest computational approaches used in modeling the properties of functionalized graphene Includes detailed methods and step-by-step guidance on key processes, supported throughout with examples Highlights the electronic properties of functionalized graphene

Properties, Characterization and Functionalization of Graphene

Properties, Characterization and Functionalization of Graphene
Eigenschaften, Charakterisierung und Funktionalisierung Von Graphen

by Jan Moritz Englert

  • Publisher : Unknown Publisher
  • Release : 2013
  • Pages : 229
  • ISBN : 9876543210XXX
  • Language : En, Es, Fr & De
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Functionalized Graphene Nanocomposites and Their Derivatives

Functionalized Graphene Nanocomposites and Their Derivatives
Synthesis, Processing and Applications

by Mohammad Jawaid,Rachid Bouhfid,Abou el Kacem Qaiss

  • Publisher : Elsevier
  • Release : 2018-11-01
  • Pages : 368
  • ISBN : 0128145536
  • Language : En, Es, Fr & De
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Functionalized Graphene Nanocomposites and Their Derivatives: Synthesis, Processing and Applications explains how the functionalization technique is used to create graphene nanocomposites, also exploring its current uses in industrial applications. Graphene-based nanocomposites are one of the major advancements in polymer-based materials, thus the synthesis, nanoscale dimensions, high aspect ratio, mechanical, electrical and thermal properties of graphene and its derivative have all been major areas of research in the last decade. This important reference covers these updates and is a critical book for those working in the fields of materials processing and characterization. Explains how graphene is functionalized and used in the fabrication of nanocomposites for a range of applications Explores why the properties of functionalized graphene make it such a useful, versatile material Describes, in detail, the functionalization process for utilization in graphene

Handbook of Graphene

Handbook of Graphene
Growth, Synthesis, and Functionalization

by Edvige Celasco,Alexander Chaika

  • Publisher : John Wiley & Sons
  • Release : 2019-06-10
  • Pages : 672
  • ISBN : 1119468612
  • Language : En, Es, Fr & De
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Handbook of Graphene, Volume 1, essentially focuses on graphene growth, synthesis, and functionalization in order to realize optimized graphene-based nanostructures which can be utilized for various applications. This handbook provides detailed and up-to-date overviews of the synthesis and functionalization of graphene on various substrates (metallic and semiconducting), their properties and possible application methods. In particular, the chapters cover: - Optimization of graphene growth and challenges for synthesis of high-quality graphene and graphite in metallic materials; - Exfoliation of graphene sheets obtained by sonication, ball milling and use of polymers and surfactants; - Structure, electronic properties, functionalization methods, and prospects of epitaxial graphene grown on hexagonal and cubic silicon carbide substrates; - Growth of graphene on Si(111) wafers via direct deposition of solid-state carbon atom and characterization of graphene-on-silicon films; - Chemical reactivity and modification of electronical properties of graphene grown on Ni(111); - Enhancement of the cell wall strength and stability of foam structure utilizing graphene; - Influence of applied strain and magnetic field on the electronic and transport properties of graphene with different kinds of defects; - Application of hydrogen functionalized graphene in spintronic nanodevices; - Electrochemistry and catalytic properties of graphene-based materials; - Functionalization of graphene with molecules and/or nanoparticles for advanced applications such as flexible electronics, biological systems, ink-jet applications and coatings; - Graphene-based composite materials devoted to electrochemical applications such as supercapacitors, lithium ion batteries and electrode material; - Three-dimensional graphene-based structures which preserve the intrinsic properties of 2D graphene and provide advanced functionalities with desired characteristics in a wide range of applications such as sensors, batteries, supercapacitors, fuel cells, etc.; - Carbon allotropes between diamond and graphite, which allow creating semiconductor properties in graphene and related structures. The 18 chapters of this handbook represent deep and very stimulating contributions to the processes of growth, synthesis and functionalization of graphene for several potential applications. This book is intended for students and active researchers in the field of graphene who are currently investigating the fundamental properties of this amazing low-dimensional material and its applications in micro- and nanotechnologies. It is also necessary reading for entrepreneurs and industrialists because it discusses a variety of possible applications of graphene and different ways of improving the quality of synthesized graphene.

Surface Functionalization of Graphene with Polymers for Enhanced Properties

Surface Functionalization of Graphene with Polymers for Enhanced Properties
A Book

by Wenge Zheng

  • Publisher : Unknown Publisher
  • Release : 2013
  • Pages : 329
  • ISBN : 9876543210XXX
  • Language : En, Es, Fr & De
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Surface Functionalization of Graphene with Polymers for Enhanced Properties.

Chemically Derived Graphene

Chemically Derived Graphene
Functionalization, Properties and Applications

by Kintao Zhang

  • Publisher : Royal Society of Chemistry
  • Release : 2018-05-10
  • Pages : 383
  • ISBN : 1788010809
  • Language : En, Es, Fr & De
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A comprehensive overview of the recent and state-of-the-art research on chemically derived graphene materials for different applications.

Functionalization of Graphene

Functionalization of Graphene
A Book

by Vasilios Georgakilas

  • Publisher : John Wiley & Sons
  • Release : 2014-04-03
  • Pages : 424
  • ISBN : 352767277X
  • Language : En, Es, Fr & De
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All set to become the standard reference on the topic, this book covers the most important procedures for chemical functionalization, making it an indispensable resource for all chemists, physicists, materials scientists and engineers entering or already working in the field. Expert authors share their knowledge on a wide range of different functional groups, including organic functional groups, hydrogen, halogen, nanoparticles and polymers.

Advances in Graphene Science

Advances in Graphene Science
A Book

by Mahmood Aliofkhazraei

  • Publisher : BoD – Books on Demand
  • Release : 2013-07-31
  • Pages : 282
  • ISBN : 9535111825
  • Language : En, Es, Fr & De
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Graphene is proving to be the magic material of the 21th century. It is widely accepted that it is the strongest material ever studied and can be an efficient substitute for silicon. Besides, fascinating properties of graphene, such as the highest electrical conductivity among the discovered substances, have dramatically shocked science and technology world. Graphene is a carbon based layer with high atomic density. Its extraordinary characteristics such as extremely high mechanical strength, hardness, and adjustable thermal and electrical conductivity, as well as excellent surface and optical feature through chemical marking, have received great deal of attention by many researchers. This book collects new advances of this interesting nanomaterial.

Controlled Functionalization and Assembly of Graphene Nanostructures for Sensing and Energy Storage

Controlled Functionalization and Assembly of Graphene Nanostructures for Sensing and Energy Storage
A Book

by Enoch A Nagelli,OhioLINK Electronic Theses and Dissertations Center

  • Publisher : Unknown Publisher
  • Release : 2014
  • Pages : 255
  • ISBN : 9876543210XXX
  • Language : En, Es, Fr & De
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The superior electron carrier mobility, thermal conductivity, and mechanical properties of graphene have led to the rapid development of graphene-based applications for high speed electronics, chemical and biological sensing, optoelectronics, energy storage and conversion. However, the incorporation of graphene into these applications requires the precise connection of individual sheets at the molecular level with other materials where chemical interaction is significant. In this regard, the chemical functionalization of graphene has played a critical role in facilitating the integration of graphene into useful "building-blocks" or functional components in these applications. The functionalization of graphene can alter its electronic band structure, doping, and affinity for other organic, inorganic, and biological materials. The site specific functionalization of graphene is essential to modify the region-specific surface properties to gain specific characteristics required for particular applications and to covalently/non-covalently link graphene sheets of different properties together into various graphene-based devices. Controlled chemical modification could be a very useful approach to various multifunctional systems critical to applications such as nanoelectronics, nanophotonics, nanosensors, and nanoenergy systems. We describe a simple and effective modification method for functionalizing the two opposite surfaces of individual graphene sheets with different nanoparticles in either a patterned or non-patterned fashion. The asymmetric and patterned functionalization of graphene sheets with each of their two opposite surfaces attached by ZnO and Au NPs can serve as a platform upon which to build high performance electronics and photonic devices. In addition, we develop a novel approach for multicomponent symmetrical patterning metal/metal oxide nanoparticles on graphene involving region-specific plasma treatment, followed by region-selective substrate-enhanced electro-less deposition of Au nanoparticles and solution alkalization formation of Fe3O4 nanoparticles. We demonstrated that metal and metal nanoparticle functionalized graphene can enhance the sensing capability and selectivity for vapors. A miniaturized gas sensor array based on graphene exhibiting great room-temperature sensing properties for various selective vapors and the potential for cost-effective graphene-based sensors was developed. These functionalization methods for spatial micro- and nanopatterning of graphene chemistry in both covalent and noncovalent functionalization schemes can be crucial for further the enhancement of graphene-based devices. Moreover, there is a pressing need to integrate graphene sheets into multidimensional and multifunctional systems with spatially well-defined configurations. The controlled assembly of graphene films still remains to be a challenge. Self-assembly has been recognized as an effective strategy for the bottom-up synthesis of 3D macrostructures using graphene sheets as building blocks. Here we report a novel, simplistic, and scalable methodology utilizing the Langmuir-Schaefer technique for the controlled transfer and assembly of graphene onto any substrate for hierarchical organization into large-scale multi-dimensional functional materials for diverse applications. This novel method of graphene assembly can lead to research and development of next generation of high performance materials and structures by providing a scientific rationale that will enable bold innovative concepts for engineered hybrid structures.

Effects of Graphene Functionalization on Mechanical Properties of Carbon Fiber Laminate Composites

Effects of Graphene Functionalization on Mechanical Properties of Carbon Fiber Laminate Composites
Subtitle

by Rifath Mahmud Rony Shagor

  • Publisher : Unknown Publisher
  • Release : 2015
  • Pages : 109
  • ISBN : 9876543210XXX
  • Language : En, Es, Fr & De
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Graphene is a marvelous structure that has an incredible mechanical, electrical, and thermal properties. However, graphene fails to retain its outstanding properties during agglomeration due to its enormous specific surface area. To solve this problem, an established functionalization coating technique whereby silane molecules are applied to the pristine graphene surface improves its dispersion and stability in a polymeric composite. In this thesis, functionalized graphene was incorporated with a carbon fiber-reinforced polymer (CFRP) composite to improve its mechanical and viscoelastic properties. Successful integration of the 0.5 wt% silanized graphene in the CFRP composite leads to the improvement of ultimate tensile strength up to 58.41% from the base composite, with 8.44% improvement from the same amount of pristine graphene CFRP composite. In the evaluation of tensile strength, the 0.25 wt% and 1 wt% silanized graphene composites outperformed pristine graphene composites by 10.64% and 16.71%, respectively. Additionally, there was 7.35%, 9.97%, and 13.5% tensile modulus improvement in the 0.25 wt%, 0.5 wt%, and 1 wt% of silanized graphene, respectively, compared with pristine graphene composites. Fourier transform infrared spectroscopy (FTIR) and scanning electron microscopy (SEM) tests were used to characterize the graphene and silanized graphene, and C-scan was performed for the qualitative analysis of the manufactured CFRP nanocomposites. A further study using dynamic scanning calorimetry (DSC) and dynamic mechanical analysis (DMA) confirmed a staggering glass transition temperature (Tg) shift of about 19.55oC for 0.25 wt% silanized graphene nanoinclusion. However, the highest amount (1 wt%) of graphene or silanized graphene degraded the mechanical strength but promisingly improved the viscoelastic characteristics of the CFRP composites. Therefore, the functionalized graphene proved to be a better candidate against pristine graphene in the development of graphene-filled CFRP nanocomposites.

The Effect of Functionalized Versus Unmodified Graphene Oxide on Polyimide Nanocomposite Properties

The Effect of Functionalized Versus Unmodified Graphene Oxide on Polyimide Nanocomposite Properties
A Book

by Natalie V. Hudson-Smith

  • Publisher : Unknown Publisher
  • Release : 2015
  • Pages : 92
  • ISBN : 9876543210XXX
  • Language : En, Es, Fr & De
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Abstract Polyimides are a commercially useful material, typically used in air and space applications due to high heat resistance, impressive mechanical strength, and self-extinguishing properties. In recent years, graphene has come of interest in the material science world. However, the pristine, carbon-honeycomb allotrope is extremely hydrophobic, chemically unreactive and it is therefore difficult, if not impossible, to disperse graphene nanoparticles as single nanosheets into polar solvents used typically used for polymerization and synthesis. Focus has shifted to graphene oxide (GO); the honeycomb structure of graphene with oxygen-containing functional groups on the surface. Incorporation of GO into polyimides is shown to improve mechanical properties, increase gas barrier properties and to increase water solvent resistance along with other solvents. Functionalization of GO sheets with monomer components of the chosen polymer results in further improvements of these properties. Here we demonstrate that tailoring of GO to be compatible with polyimide resins is a valuable technique in enhancing GO-polymer composite properties.

Graphene for Transparent Conductors

Graphene for Transparent Conductors
Synthesis, Properties and Applications

by Qingbin Zheng,Jang-Kyo Kim

  • Publisher : Springer
  • Release : 2015-07-01
  • Pages : 220
  • ISBN : 1493927698
  • Language : En, Es, Fr & De
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This book provides a systematic presentation of the principles and practices behind the synthesis and functionalization of graphene and grapheme oxide (GO), as well as the fabrication techniques for transparent conductors from these materials. Transparent conductors are used in a wide variety of photoelectronic and photovoltaic devices, such as liquid crystal displays (LCDs), solar cells, optical communication devices, and solid-state lighting. Thin films made from indium tin oxide (ITO) have thus far been the dominant source of transparent conductors, and now account for 50% of indium consumption. However, the price of Indium has increased 1000% in the last 10 years. Graphene, a two-dimensional monolayer of sp2-bonded carbon atoms, has attracted significant interest because of its unique transport properties. Because of their high optical transmittance and electrical conductivity, thin film electrodes made from graphene nanosheets have been considered an ideal candidate to replace expensive ITO films. Graphene for Transparent Conductors offers a systematic presentation of the principles, theories and technical practices behind the structure–property relationship of the thin films, which are the key to the successful development of high-performance transparent conductors. At the same time, the unique perspectives provided in the applications of graphene and GO as transparent conductors will serve as a general guide to the design and fabrication of thin film materials for specific applications.

Synthesis, Properties and Electronics of Graphene Nanoribbons

Synthesis, Properties and Electronics of Graphene Nanoribbons
A Book

by Xinran Wang

  • Publisher : Unknown Publisher
  • Release : 2010
  • Pages : 329
  • ISBN : 9876543210XXX
  • Language : En, Es, Fr & De
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Graphene, a two-dimensional single atomic layer of graphite, has emerged as a material with interesting physical and chemical properties and high potential for various applications such as sensors, transparent electrodes and electronics. Due to high carrier mobility (up to ~15,000cm2/Vs), graphene has gained much interest as a possible candidate to extend beyond silicon complementary metal-oxide-semiconductor (CMOS) technology for future nano-electronics. Bulk graphene is a semi-metal with zero bandgap, not suitable for high on/off ratio transistors. However, narrow (~ a few nanometer) graphene nanoribbons (GNRs) have been theoretically predicted to be semiconductors that afford high performance room temperature field-effect transistors (FETs). This thesis focuses on the synthesis, physical and chemical properties and electronic devices of GNRs down to a few nanometers wide. We address several critical issues towards large scale graphene electronics and propose a roadmap to achieve this goal. In the first part of this thesis, I will show a chemical route to produce GNRs with width below 10 nanometers, as well as single ribbons with varying widths along their lengths or containing lattice defined graphene junctions. The GNRs were solution phase derived, stably suspended in solvents with noncovalent polymer functionalization, and exhibited ultra-smooth edges with possibly well defined zigzag or armchair edge structures. Electrical transport experiments showed that the bandgaps of these GNRs are inversely proportional to the widths, which confirms that quantum confinement is responsible for the bandgap opening. Unlike single-walled carbon nanotubes (SWNTs), all of the GNRs narrower than ~5nm are semiconductors that afford graphene FETs with on/off ratios of higher than ~105 at room temperature. We then study the chemically derived narrow semiconducting GNR-FETs on 10nm SiO2 systematically. We find that the on state current density can be as high as ~2000[mu]A/[mu]m, carrier mobility is ~200cm2/Vs and scattering mean free path is ~10 nm. Scattering mechanisms by edges, acoustic phonon, and defects are discussed. The semiconducting GNR-FETs are comparable to small diameter (d~1:2 nm) semiconducting SWNT-FETs in on-state current density and on/off ratio. In the second part of this thesis, I will talk about complementary electronics of GNRs. As made GNR device are usually p-doped by adsorbates, but for device applications, it would be useful to access the n-doped material. Individual graphene nanoribbons could be covalently functionalized by nitrogen species through high-power electrical joule heating in NH3, leading to n-type electronic doping consistent with theory. The formation of the carbon-nitrogen bond should occur mostly at the edges of graphene where chemical reactivity is high. We fabricate the first n-type graphene FET that operates at room temperature. Spectroscopic study of graphene oxide (GO) annealed in NH3 provides direct evidence of nitrogen incorporation and sheds light on the possible configurations of nitrogen in carbon networks. In the third part of this thesis, I study the interface between graphene and high dielectric constant (high-k) metal oxides, which are widely used in current silicon technology as gate dielectrics of transistors. We use atomic layer deposition (ALD) to deposit the metal oxides. We find that ALD of metal oxides gives no direct deposition on defect-free pristine graphene. On the edges and defect sites, however, dangling bonds or functional groups can react with ALD precursors to afford active oxide growth. This leads to an interesting and simple way to decorate and visualize defects in graphene. By noncovalent functionalization of graphene with carboxylate-terminated perylene molecules, one can coat graphene with densely packed polar groups for uniform ALD of high-k dielectrics. Uniform high-k coverage is achieved on large pieces of graphene sheets with a size of greater than 5 [mu]m. This method opens the possibility of integrating ultrathin high-k dielectrics in future graphene electronics. Finally, I will describe a scalable lithographic approach to make GNRs narrower than 10nm for future logic applications. We devise a gas phase chemical approach to etch and shrink graphene from the edges without damaging its basal plane. The reaction involves high temperature oxidation of graphene in a slight reducing environment to afford controlled etch rate ([less than or equal to] ~1nm/min). We then fabricate ~20-30nm wide GNR arrays by electron beam lithography, and use the gas phase etching chemistry to narrow the ribbons down to

Enhanced Thermal and Mechanical Properties of Polymer Reinforced with Slightly Functionalized Graphene Nanoplatelets

Enhanced Thermal and Mechanical Properties of Polymer Reinforced with Slightly Functionalized Graphene Nanoplatelets
A Book

by U. O. Uyor,A. P. I. Popoola,O. M. Popoola,V. S. Aigbodion

  • Publisher : Unknown Publisher
  • Release : 2019
  • Pages : 12
  • ISBN : 9876543210XXX
  • Language : En, Es, Fr & De
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Slightly oxidized graphene nanoplatelets (GNPs) were functionalized using 3-hydroxytyramine hydrobromide. The functionalized GNPs, denoted as fGNPs, were examined using Fourier transform infrared and a Raman spectrometer, which revealed a slight reduction in the sp2network domain compared with unmodified GNPs. Compared with previous reports on functionalized highly oxidized graphene, the degree of the sp2structural destruction was less, as revealed by Raman analysis. The aim was to address the challenges of high agglomeration of graphene in polymer matrix and high destruction of graphenes conjugal structure during functionalization, which deteriorates graphenes excellent properties and makes it less effective in improving the polymers properties. This was achieved by slight functionalization of GNPs because they contained little oxygen functional groups. In this study, a thermal conductivity increase of about 295 % was recorded when 6.67wt. % fGNPs were incorporated into the poly(vinylidene fluoride) (PVDF) matrix. Also, with 3.34wt. % of the GNPs composite, the tensile strength and Youngs modulus were measured with an increase of about 64 % and 100 %, respectively. The enhanced properties of the polymer nanocomposites were due to better dispersion of fGNPs and interaction with the polymer matrix compared to unfunctionalized GNPs composites as was indicated by a scanning electron microscope. The composites were prepared by solution blending and melt compounding process. Such composites can find application in automobile and aerospace industries in which good mechanical and thermal properties are required.

Graphene Functionalization Strategies

Graphene Functionalization Strategies
From Synthesis to Applications

by Anish Khan,Mohammad Jawaid,Bernaurdshaw Neppolian,Abdullah M. Asiri

  • Publisher : Springer Nature
  • Release : 2019-10-17
  • Pages : 398
  • ISBN : 9813290579
  • Language : En, Es, Fr & De
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This book discusses various aspects of graphene fictionalization strategies from inorganic oxides and organic moieties including preparation, design, and characterization of functionalization material and its applications. Including illustrations and tables summarizing the latest research on manufacturing, design, characterization and applications of graphene functionalization, it describes graphene functionalization using different techniques and materials and highlights the latest technologies in the field of manufacturing and design. This book is a valuable reference resource for lecturers, students, researchers and industrialists working in the field of material science, especially polymer composites.

Functionalizing Graphene and Carbon Nanotubes

Functionalizing Graphene and Carbon Nanotubes
A Review

by Filipe Vargas Ferreira,Luciana De Simone Cividanes,Felipe Sales Brito,Beatriz Rossi Canuto de Menezes,Wesley Franceschi,Evelyn Alves Nunes Simonetti,Gilmar Patrocínio Thim

  • Publisher : Springer
  • Release : 2016-08-22
  • Pages : 63
  • ISBN : 3319351109
  • Language : En, Es, Fr & De
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This book compiles all current information on the different types of functionalization of carbon nanotubes (CNTs) and graphene, both covalent and non-covalent. The book starts with a general overview of the synthesis, characterization and application of functionalized CNTs and graphene. Special attention is dedicated to the characterization of functionalized materials, a topic rarely addressed on the literature. The authors provide a comparison between the functionalization of these two types of carbon materials.

Processing and Proeprties of Novel Graphene-based PLA Bionanocomposites

Processing and Proeprties of Novel Graphene-based PLA Bionanocomposites
A Book

by Yu Fu,Washington State University. School of Mechanical and Materials Engineering

  • Publisher : Unknown Publisher
  • Release : 2013
  • Pages : 329
  • ISBN : 9781303465338
  • Language : En, Es, Fr & De
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A novel one-step approach was developed for the pH-triggered electrochemically interacted exfoliation of graphene sheets in graphite oxide and simultaneous reduction and functionalization with the aid of the ionic liquid. The results indicated that, with the aid of the IL during the reaction, the resulting functionalized graphene showed improved organophilicity, wettability, interfacial interactions, as well as significant resistance to thermal degradation.

Polymer Composites with Functionalized Nanoparticles

Polymer Composites with Functionalized Nanoparticles
Synthesis, Properties, and Applications

by Krzysztof Pielichowski,Tomasz M. Majka

  • Publisher : Woodhead Publishing
  • Release : 2018-09-22
  • Pages : 504
  • ISBN : 0128140658
  • Language : En, Es, Fr & De
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Polymer Composites with Functional Nanoparticles: Synthesis, Properties, and Applications reviews the latest research in the area of polymer nanocomposites and functionalized nanoparticles, providing an introduction for those new to the field, and supporting further research and development. The book helps researchers and practitioners better understand the key role of nanoparticle functionalization for improving the compatibility of inorganic metallic nanomaterials with organic polymers, and for the fabrication of nanostructured materials with special properties. A range of nanoparticles, such as carbon nanotubes are covered, along with descriptions of the methods of functionalization to support better compatibility with polymer matrices. The book also discusses the various applications of this technology, including uses in electronics and the medical and energy industries. Summarizes the latest research in functionalized nanoparticles for modification of polymer matrices, providing a valuable platform for further research Includes functionalization of a range of nanoparticles for incorporation into nanocomposites, including carbon nanotubes, graphene, gold and silver, silica and clay Provides detailed coverage of application areas, including energy, electronics, biomedical applications, and end-of-life considerations

Polymer Functionalized Graphene

Polymer Functionalized Graphene
A Book

by Arun Kumar Nandi

  • Publisher : Royal Society of Chemistry
  • Release : 2021-06-28
  • Pages : 434
  • ISBN : 1788019687
  • Language : En, Es, Fr & De
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There is an immense variety of research on polymer functionalized graphene (PFG). Functionalization of graphene is necessary for improvement of the compatibility with polymers. Applications of these graphene polymer hybrids include in chemical and biological sensing, photovoltaic devices, supercapacitors and batteries, dielectric materials and drug/gene delivery vehicles. This book will shed light on the synthesis, properties and applications of these new materials, covering two methods (covalent and noncovalent) for producing polymer functionalized graphene. Chapters cover physical, optical, mechanical and electronic properties, applications of polymer functionalized graphene in energy harvesting and storage, and uses in biomedicine and bioengineering. Written by an expert in the field, Polymer Functionalized Graphene will be of interest to graduate students and researchers in polymer chemistry and nanoscience.

Electronic Properties of Functionalized Graphene Studied with Photoemission Spectroscopy

Electronic Properties of Functionalized Graphene Studied with Photoemission Spectroscopy
A Book

by Danny Haberer-Gehrmann

  • Publisher : Unknown Publisher
  • Release : 2012
  • Pages : 127
  • ISBN : 9876543210XXX
  • Language : En, Es, Fr & De
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