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Author: Namiko Yamamoto
Publisher:
ISBN:
Category :
Languages : en
Pages : 221
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Book Description
Carbon nanotubes (CNTs) are a potential new component to be incorporated into existing aerospace structural composites for multi-functional (mechanical, electrical, thermal, etc.) property enhancement and tailoring. Traditional advanced fiber reinforced polymer composites are used for aerospace vehicles due to their high mass-specific properties. Still, improvements are desired including non-mechanical aspects, e.g., higher electrical conductivity is required for shielding layers against electromagnetic (EM) waves and lightning strike, and tailored thermal conductivity is desired for heat management. Currently, effective use of CNTs is limited in macroscopic materials due to numerous issues including difficulties in processing; favorable CNT properties have not translated straightforwardly into macroscopic property enhancement. Factors that cause such scaling and compositing effects include CNT quality, morphology (length, entanglement, alignment, etc.), and CNT-medium and inter-CNT boundary properties. Evaluation of these factors through process-structure-property relations has been difficult due to inconsistency and poor quantification of CNT composite morphology. In this work, a complete characterization of consistent CNT-polymer composite samples with controlled CNT morphology was acquired for the first time. Aligned CNT polymer nanocomposites (A-CNT-PNCs) were fabricated with multi-walled carbon nanotubes (MWNTs) with varying volume fraction (VCNT) between 1-20% embedded in an aerospace-grade epoxy. A-CNTPNC surfaces were controlled to nano-scale roughness for effective CNT-electrode contact, and interface boundary effects were eliminated using unique test techniques. Benchmark electrical and thermal property measurements of A-CNT-PNCs were obtained using complementary bulk and local measurement techniques, with clear structure-property relations due to the controlled, quantified, and non-isotropic CNT morphology. The data were interpreted using both analytical and numerical models to evaluate the effects of the above critical scaling factors, particularly interface properties at CNT-polymer and inter-CNT contacts. Electrical conductivities were measured to have a linear increase with VCNT, resulting in ~104 S/m (axial) and ~102 S/m (transverse) with -20% VCNT, much higher than previously measured data of any CNT-thermoset PNCs in the literature. Meanwhile, the extracted per-CNT resistance, 107 Q, is comparable to individually measured values in the literature, confirming that scaling and compositing effects can be minimized. Thermal conductivities, both axial and transverse, were experimentally observed to rapidly increase at a certain high VCNT (-10%). This experimental observation is novel, as CNT-PNCs have never been fabricated and tested with such high VCNT or with non-isotropy from CNT alignment. When studied analytically and numerically, this non-linear behavior is partially explained by thermal boundary resistances, mainly at CNTpolymer contacts (quantified as ~10-8 m2K/W). Although A-CNT-PNC thermal conductivity is still low in the VCNT range tested (-4 W/mK with 16% VCNT), the rapid increase trend suggests the potential for further enhancement of thermal conduction. These experimental data sets demonstrate that individual CNT properties can be scaled when morphology is controlled, suggesting a specific means to further composite property improvement: greater CNT alignment to avoid inter-CNT contacts for electrical transport, and CNT-polymer and inter-CNT interface enhancement to reduce resistances for thermal transport. Based on the above, a model macroscopic nano-engineered composite (CNTs, fibers, and polymer) was fabricated through direct growth of radially aligned CNTs on 11 pm-diameter alumina fibers in a woven cloth and hand lay-up. Measured laminate electrical and thermal properties (-1 W/mK and -100 S/m) were consistent with the A-CNT-PNC study, and confirmed the CNT-implemented composite's potential for applications such as electromagnetic interference shielding. The benchmark experimental data and findings and multi-scale framework established in this work can contribute to optimal use of CNTs and other conductive nano-particles in macroscopic materials for numerous applications: damage sensing in airplane structures, electrical interconnects, thermal interface materials, and power electrode or storage materials. Future work includes further understanding of transport limiting factors using improved models that can accommodate more complex CNT geometries and associated boundary effects, and tailoring of macroscopic CNT composites by extending CNT-growth substrates and matrices for a variety of applications.
Author: Namiko Yamamoto
Publisher:
ISBN:
Category :
Languages : en
Pages : 221
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Book Description
Carbon nanotubes (CNTs) are a potential new component to be incorporated into existing aerospace structural composites for multi-functional (mechanical, electrical, thermal, etc.) property enhancement and tailoring. Traditional advanced fiber reinforced polymer composites are used for aerospace vehicles due to their high mass-specific properties. Still, improvements are desired including non-mechanical aspects, e.g., higher electrical conductivity is required for shielding layers against electromagnetic (EM) waves and lightning strike, and tailored thermal conductivity is desired for heat management. Currently, effective use of CNTs is limited in macroscopic materials due to numerous issues including difficulties in processing; favorable CNT properties have not translated straightforwardly into macroscopic property enhancement. Factors that cause such scaling and compositing effects include CNT quality, morphology (length, entanglement, alignment, etc.), and CNT-medium and inter-CNT boundary properties. Evaluation of these factors through process-structure-property relations has been difficult due to inconsistency and poor quantification of CNT composite morphology. In this work, a complete characterization of consistent CNT-polymer composite samples with controlled CNT morphology was acquired for the first time. Aligned CNT polymer nanocomposites (A-CNT-PNCs) were fabricated with multi-walled carbon nanotubes (MWNTs) with varying volume fraction (VCNT) between 1-20% embedded in an aerospace-grade epoxy. A-CNTPNC surfaces were controlled to nano-scale roughness for effective CNT-electrode contact, and interface boundary effects were eliminated using unique test techniques. Benchmark electrical and thermal property measurements of A-CNT-PNCs were obtained using complementary bulk and local measurement techniques, with clear structure-property relations due to the controlled, quantified, and non-isotropic CNT morphology. The data were interpreted using both analytical and numerical models to evaluate the effects of the above critical scaling factors, particularly interface properties at CNT-polymer and inter-CNT contacts. Electrical conductivities were measured to have a linear increase with VCNT, resulting in ~104 S/m (axial) and ~102 S/m (transverse) with -20% VCNT, much higher than previously measured data of any CNT-thermoset PNCs in the literature. Meanwhile, the extracted per-CNT resistance, 107 Q, is comparable to individually measured values in the literature, confirming that scaling and compositing effects can be minimized. Thermal conductivities, both axial and transverse, were experimentally observed to rapidly increase at a certain high VCNT (-10%). This experimental observation is novel, as CNT-PNCs have never been fabricated and tested with such high VCNT or with non-isotropy from CNT alignment. When studied analytically and numerically, this non-linear behavior is partially explained by thermal boundary resistances, mainly at CNTpolymer contacts (quantified as ~10-8 m2K/W). Although A-CNT-PNC thermal conductivity is still low in the VCNT range tested (-4 W/mK with 16% VCNT), the rapid increase trend suggests the potential for further enhancement of thermal conduction. These experimental data sets demonstrate that individual CNT properties can be scaled when morphology is controlled, suggesting a specific means to further composite property improvement: greater CNT alignment to avoid inter-CNT contacts for electrical transport, and CNT-polymer and inter-CNT interface enhancement to reduce resistances for thermal transport. Based on the above, a model macroscopic nano-engineered composite (CNTs, fibers, and polymer) was fabricated through direct growth of radially aligned CNTs on 11 pm-diameter alumina fibers in a woven cloth and hand lay-up. Measured laminate electrical and thermal properties (-1 W/mK and -100 S/m) were consistent with the A-CNT-PNC study, and confirmed the CNT-implemented composite's potential for applications such as electromagnetic interference shielding. The benchmark experimental data and findings and multi-scale framework established in this work can contribute to optimal use of CNTs and other conductive nano-particles in macroscopic materials for numerous applications: damage sensing in airplane structures, electrical interconnects, thermal interface materials, and power electrode or storage materials. Future work includes further understanding of transport limiting factors using improved models that can accommodate more complex CNT geometries and associated boundary effects, and tailoring of macroscopic CNT composites by extending CNT-growth substrates and matrices for a variety of applications.
Author: Roham Rafiee
Publisher: Elsevier
ISBN: 0323482228
Category : Science
Languages : en
Pages : 588
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Book Description
Carbon Nanotube-Reinforced Polymers: From Nanoscale to Macroscale addresses the advances in nanotechnology that have led to the development of a new class of composite materials known as CNT-reinforced polymers. The low density and high aspect ratio, together with their exceptional mechanical, electrical and thermal properties, render carbon nanotubes as a good reinforcing agent for composites. In addition, these simulation and modeling techniques play a significant role in characterizing their properties and understanding their mechanical behavior, and are thus discussed and demonstrated in this comprehensive book that presents the state-of-the-art research in the field of modeling, characterization and processing. The book separates the theoretical studies on the mechanical properties of CNTs and their composites into atomistic modeling and continuum mechanics-based approaches, including both analytical and numerical ones, along with multi-scale modeling techniques. Different efforts have been done in this field to address the mechanical behavior of isolated CNTs and their composites by numerous researchers, signaling that this area of study is ongoing. Explains modeling approaches to carbon nanotubes, together with their application, strengths and limitations Outlines the properties of different carbon nanotube-based composites, exploring how they are used in the mechanical and structural components Analyzes the behavior of carbon nanotube-based composites in different conditions
Author: Dimitrios Tasis
Publisher: Royal Society of Chemistry
ISBN: 1782625828
Category : Technology & Engineering
Languages : en
Pages : 293
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Book Description
Chemically-modified carbon nanotubes (CNTs) exhibit a wide range of physical and chemical properties which makes them an attractive starting material for the preparation of super-strong and highly-conductive fibres and films. Much information is available across the primary literature, making it difficult to obtain an overall picture of the state-of-the-art. This volume brings together some of the leading researchers in the field from across the globe to present the potential these materials have, not only in developing and characterising novel materials but also the devices which can be fabricated from them. Topics featured in the book include Raman characterisation, industrial polymer materials, actuators and sensors and polymer reinforcement, with chapters prepared by highly-cited authors from across the globe. A valuable handbook for any academic or industrial laboratory, this book will appeal to newcomers to the field and established researchers alike.
Author: Moones Rahmandoust
Publisher: Springer
ISBN: 3319002511
Category : Technology & Engineering
Languages : en
Pages : 246
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Book Description
This volume presents the characterization methods involved with carbon nanotubes and carbon nanotube-based composites, with a more detailed look at computational mechanics approaches, namely the finite element method. Special emphasis is placed on studies that consider the extent to which imperfections in the structure of the nanomaterials affect their mechanical properties. These defects may include random distribution of fibers in the composite structure, as well as atom vacancies, perturbation and doping in the structure of individual carbon nanotubes.
Author: Mohamed Berber
Publisher: BoD – Books on Demand
ISBN: 9535124692
Category : Science
Languages : en
Pages : 508
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Book Description
This book shows the recent advances of the applications of carbon nanotubes (CNTs), in particular, the polymer functionalized carbon nanotubes. It also includes a comprehensive description of carbon nanotubes' preparation, properties, and characterization. Therefore, we have attempted to provide detailed information about the polymer-carbon nanotube composites. With regard to the unique structure and properties of carbon nanotubes, a series of important findings have been reported. The unique properties of carbon nanotubes, including thermal, mechanical, and electrical properties, after polymer functionalization have been documented in detail. This book comprises 18 chapters. The chapters include different applications of polymer functionalization CNTs, e.g. photovoltaic, biomedical, drug delivery, gene delivery, stem cell therapy, thermal therapy, biological detection and imaging, electroanalytical, energy, supercapacitor, and gas sensor applications.
Author: Zhifeng Ren
Publisher: Springer Science & Business Media
ISBN: 3642304907
Category : Science
Languages : en
Pages : 310
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Book Description
This book gives a survey of the physics and fabrication of carbon nanotubes and their applications in optics, electronics, chemistry and biotechnology. It focuses on the structural characterization of various carbon nanotubes, fabrication of vertically or parallel aligned carbon nanotubes on substrates or in composites, physical properties for their alignment, and applications of aligned carbon nanotubes in field emission, optical antennas, light transmission, solar cells, chemical devices, bio-devices, and many others. Major fabrication methods are illustrated in detail, particularly the most widely used PECVD growth technique on which various device integration schemes are based, followed by applications such as electrical interconnects, nanodiodes, optical antennas, and nanocoax solar cells, whereas current limitations and challenges are also be discussed to lay the foundation for future developments.
Author: Mohammed Rahman
Publisher: BoD – Books on Demand
ISBN: 1789230527
Category : Technology & Engineering
Languages : en
Pages : 366
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Book Description
The book Carbon Nanotubes - Recent Progress contains a number of recent researches on synthesis, growth, characterization, development, and potential applications on carbon materials especially CNTs in nanoscale. It is a promising novel research from top to bottom that has received a lot of interest in the last few decades. It covers the advanced topics on the physical, chemical, and potential applications of CNTs. Here, the interesting reports on cutting-edge science and technology related to synthesis, morphology, control, hybridization, and prospective applications of CNTs are concluded. This potentially unique work offers various approaches on the R
Author: Anna Boczkowska
Publisher: Mdpi AG
ISBN: 9783036522012
Category : Technology & Engineering
Languages : en
Pages : 128
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Book Description
The Special issue, "Carbon nanotube-based nanocomposites", provides an extensive overview of current trends in the area of polymer matrix nanocomposites based on carbon nanotubes (CNTs) from the papers contributed by internationally recognized specialists. The Special Issue brings together 7 papers that deal with the various aspects of processing, as well as experimental and analytical approaches to carbon nanotube-based nanocomposites fabrication, characterization and application. Each paper demonstrates how enhancements in materials, processes and characterization techniques can improve performance in the field of engineering. The Special issue gives a unique opportunity to discover the latest research on carbon nanotube-based nanocomposites from different laboratories. Numerous references are given at the end of each paper to enable the reader to explore the topics covered in greater detail. Most of the papers describe the improvement of electrical and mechanical properties of polymer-based nanocomposites due to the application of CNTs, independently on the matrix used: (ethylene vinyl acetate) copolymer, hot melt copolyamides, epoxy and silicone resins. In each case, the relationships between the processing parameters and microstructure of obtained nanocomposites were described. The synergistic effect of hybrid nanofillers was also explored in nanocomposites with carbon and halloysite nanotubes. The effect of carbon nanotubes on the wear behavior of nanocomposites based on epoxy resin was investigated as well. The original results on the synthesis and characterization of composite shear thickening fluids containing carbon nanofillers are presented. The addition of the CNTs modified the impact absorption ability of such fluids. The presented Special Issue results also proved that CNTs can be used to obtain more resistant and durable cement-based composites.
Author: Satoru Suzuki
Publisher: BoD – Books on Demand
ISBN: 9535111256
Category : Science
Languages : en
Pages : 552
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Book Description
Carbon nanotubes are rolled up graphene sheets with a quasi-one-dimensional structure of nanometer-scale diameter. In these last twenty years, carbon nanotubes have attracted much attention from physicists, chemists, material scientists, and electronic device engineers, because of their excellent structural, electronic, optical, chemical and mechanical properties. More recently, demand for innovative industrial applications of carbon nanotubes is increasing. This book covers recent research topics regarding syntheses techniques of carbon nanotubes and nanotube-based composites, and their applications. The chapters in this book will be helpful to many students, engineers and researchers working in the field of carbon nanotubes.
Author: Arvind Agarwal
Publisher: CRC Press
ISBN: 1439811504
Category : Technology & Engineering
Languages : en
Pages : 318
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Book Description
From the Foreword, written by legendary nano pioneer M. Meyyappan, Chief Scientist for Exploration Technology NASA Ames Research Center, Moffett Field, California, USA: "...there is critical need for a book to summarize the status of the field but more importantly to lay out the principles behind the technology. This is what Professor Arvind Agarwal and his co-workers ... have done here." Carbon Nanotubes: Reinforced Metal Matrix Composites reflects the authors’ desire to share the benefits of nanotechnology with the masses by developing metal matrix carbon nanotube (MM-CNT) composites for large-scale applications. Multiwall carbon nanotubes can now be produced on a large scale and at a significantly reduced cost. The book explores potential applications and applies the author’s own research to highlight critical developmental issues for different MM-CNT composites—and then outline novel solutions. With this problem-solving approach, the book explores: Advantages, limitations, and the evolution of processing techniques used for MM-CNT composites Characterization techniques unique to the study of MM-CNT composites—and the limitations of these methods Existing research on different MM-CNT composites, presented in useful tables that include composition, processing method, quality of CNT dispersion, and properties The micro-mechanical strengthening that results from adding CNT The applicability of micro-mechanics models in MM-CNT composites Significance of chemical stability for carbon nanotubes in the metal matrix as a function of processing, and its impact on CNT/metal interface and mechanical properties Computational studies that have not been sufficiently covered although they are essential to research and development The critical issue of CNT dispersion in the metal matrix, as well as a unique way to quantify CNT distribution and subsequently improve control of the processing parameters for obtaining improved properties Carbon Nanotubes: Reinforced Metal Matrix Composites paints a vivid picture of scientific and application achievements in this field. Exploring the mechanisms through which CNTs are enhancing the properties of different metal-based composites, the authors provide a roadmap to help researchers develop MM-CNT composites and choose potential materials for use in emerging areas of technology.
