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200 00$aNanotube superfiber materials $echanging engineering design /$fedited by Mark J. Schulz, Vesselin N. Shanov, Zhangzhang Yin
205   $aFirst edition.
210  1$aOxford, UK :$cWilliam Andrew,$d2014.
215   $a1 online resource (861 p.)
225 1 $aMicro & nano technologies series
300   $aDescription based upon print version of record.
311   $a1-4557-7863-X 
311   $a1-299-87505-X 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Nanotube Superfiber Materials: Changing Engineering Design; Copyright; Contents; Preface; INTRODUCTION TO NANOTUBE MATERIALS; GOALS OF SUPERFIBER RESEARCH; FUTURE PROSPECTS; MAJOR AREAS OF NANOTUBE RESEARCH; BACKGROUND NEEDED FOR STUDYING NANOTUBE MATERIALS; Acknowledgment; Editor Biographies; Chapter 1 - Introduction to Fiber Materials; 1.1 FIBERS AND NANOFIBERS; 1.2 THE CHALLENGE OF CNT YARN FIBER FABRICATION; 1.3 CONCLUSION; References; Chapter 2 - New Applications and Techniques for Nanotube Superfiber Development; 2.1 NEW APPLICATIONS FOR NANOTUBE SUPERFIBER DEVELOPMENT
327   $a2.2 NEW TECHNIQUES FOR NANOTUBE SUPERFIBER DEVELOPMENT2.3 CONCLUSIONS; Acknowledgments; References; Chapter 3 - Tailoring the Mechanical Properties of Carbon Nanotube Fibers; 3.1 INTRODUCTION; 3.2 IRRADIATION CROSS-LINKING: STRONG AND STIFF CNTS AND CNT BUNDLES; 3.3 REFORMABLE BONDING: STRONG AND TOUGH CNT BUNDLES AND FIBERS; 3.4 MATERIALS DESIGN: OPTIMIZED GEOMETRY AND STRUCTURE; 3.5 SUMMARY; Acknowledgments; References; Chapter 4 - Synthesis and Properties of Ultralong Carbon Nanotubes; 4.1 INTRODUCTION; 4.2 SYNTHESIS OF ULTRALONG CNTS BY CVD; 4.3 TUNING THE STRUCTURE OF ULTRALONG CNTS
327   $a4.4 CONCLUSIONSReferences; Chapter 5 - Alloy Hybrid Carbon Nanotube Yarn for Multifunctionality; 5.1 INTRODUCTION; 5.2 ELECTRICAL CONDUCTIVITY OF CNT YARNS; 5.3 METAL DEPOSITION ON CNT MACROSTRUCTURES; 5.4 GAS SENSING APPLICATIONS; 5.5 SUMMARY; References; Chapter 6 - Wet Spinning of CNT-based Fibers; 6.1 INTRODUCTION TO WET SPINNING; 6.2 FIBERS OBTAINED FROM THE COAGULATION OF CARBON NANOTUBES; 6.3 FIBERS OBTAINED FROM THE COAGULATION OF CNT-POLYMER MIXTURES; 6.4 CONCLUSIONS; References; Chapter 7 - Dry Spinning Carbon Nanotubes into Continuous Yarn: Progress, Processing and Applications
327   $a7.1 INTRODUCTION7.2 BASIS OF CNT ASSEMBLY IN MACROSCOPIC STRUCTURES; 7.3 FROM TEXTILE SPINNING TECHNOLOGY TO DRY CNT SPINNING; 7.4 MULTISTEP SPINNING PROCESS USING A DRAFTING SYSTEM; 7.5 SEVERAL TREATMENTS FOR CNT YARN IMPROVEMENT; 7.6 CNT-BASED COMPOSITE YARNS; 7.7 APPLICATIONS OF CNT YARNS; 7.8 CONCLUSION; Acknowledgments; References; Chapter 8 - Synthesis and Properties of Boron Nitride Nanotubes; 8.1 INTRODUCTION; 8.2 NANOTUBES: BASIC STRUCTURE; 8.3 SYNTHESIS OF BNNTS; 8.4 PROPERTIES OF BORON NITRIDE NANOTUBES; 8.5 COMPARISON OF BNNTS AND CNTS; 8.6 SUMMARY; Acknowledgments; References
327   $aChapter 9 - Boron Nitride Nanotubes, Silicon Carbide Nanotubes, and Carbon Nanotubes-A Comparison of Properties and Applica ...9.1 INTRODUCTION; 9.2 BNNT AND SICNT STRUCTURE AND SYNTHESIS; 9.3 COMPOSITES REINFORCED WITH HIGH-TEMPERATURE NANOTUBES; 9.4 APPLICATIONS OF HIGH-TEMPERATURE NANOTUBES; 9.5 CONCLUDING REMARKS; References; Chapter 10 - Carbon Nanotube Fiber Doping; 10.1 INTRODUCTION; 10.2 DOPING; 10.3 SINGLE-WALLED CARBON NANOTUBE DOPING; 10.4 MULTIWALLED CARBON NANOTUBE DOPING; 10.5 CHARACTERIZATION OF DOPED CNTS; 10.6 EXPERIMENTAL CHALLENGES IN CHARACTERIZATION; 10.7 SUMMARY
327   $aAcknowledgments
330   $aNanotube Superfiber Materials refers to different forms of macroscale materials with unique properties constructed from carbon nanotubes. These materials include nanotube arrays, ribbons, scrolls, yarn, braid, and sheets. Nanotube materials are in the early stage of development and this is the first dedicated book on the subject. Transitioning from molecules to materials is a breakthrough that will positively impact almost all industries and areas of society.    Key properties of superfiber materials are high flexibility and fatigue resistance, high energy absorption, high strength, go
410  0$aMicro & nano technologies.
606   $aNanostructured materials
608   $aElectronic books.
615  0$aNanostructured materials.
676   $a620.193
701   $aSchulz$b Mark J$0939169
701   $aShanov$b Vesselin N$0939170
701   $aYin$b Zhangzhang$0939171
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200 00$aHow and Why Does Spatial-Hearing Ability Differ among Listeners? What Is the Role of Learning and Multisensory Interactions?
210   $cFrontiers Media SA$d2016
215   $a1 online resource (253 p.)
225 1 $aFrontiers Research Topics
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330   $aSpatial-hearing ability has been found to vary widely across listeners. A survey of the existing auditory-space perception literature suggests that three main types of factors may account for this variability: - physical factors, e.g., acoustical characteristics related to sound-localization cues, - perceptual factors, e.g., sensory/cognitive processing, perceptual learning, multisensory interactions, - and methodological factors, e.g., differences in stimulus presentation methods across studies. However, the extent to which these-and perhaps other, still unidentified-factors actually contribute to the observed variability in spatial hearing across individuals with normal hearing or within special populations (e.g., hearing-impaired listeners) remains largely unknown. Likewise, the role of perceptual learning and multisensory interactions in the emergence of a multimodal but unified representation of "auditory space," is still an active topic of research. A better characterization and understanding of the determinants of inter-individual variability in spatial hearing, and of its relationship with perceptual learning and multisensory interactions, would have numerous benefits. In particular, it would enhance the design of rehabilitative devices and of human-machine interfaces involving auditory, or multimodal space perception, such as virtual auditory/multimodal displays in aeronautics, or navigational aids for the visually impaired. For this Research Topic, we have considered manuscripts that: - present new methods, or review existing methods, for the study of inter-individual differences; - present new data (or review existing) data, concerning acoustical features relevant for explaining inter-individual differences in sound-localization performance; - present new (or review existing) psychophysical or neurophysiological findings concerning spatial hearing and/or auditory perceptual learning, and/or multisensory interactions in humans (normal or impaired, young or older listeners) or other species; - discuss the influence of inter-individual differences on the design and use of assistive listening devices (rehabilitation) or human-machine interfaces involving spatial hearing or multimodal perception of space (ergonomy).
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610   $aadaptation
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610   $aHRTF (head related transfer function)
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610   $aSound Localization
610   $aspatial hearing
610   $aspectral cues
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615  7$aNeurosciences
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702   $aAndeol$b Guillaume$f1977-
702   $aMacpherson$b Ewan A.
702   $aSimpson$b Brian D.
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