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EBSCO_ocn670430515 |
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101018s2010 nyua ob 001 0 eng d |
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|a 923657710
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|a UAMI
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|a Nanomaterials :
|b properties, preparation and processes /
|c Vinicius Cabral and Renan Silva, editors.
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|a New York :
|b Nova Science Publishers,
|c ©2010.
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|a 1 online resource (xvi, 412 pages) :
|b illustrations
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|a text
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|a Nanotechnology science and technology series
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|a Includes bibliographical references and index.
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|a Print version record.
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|a Nanomaterials: properties, preparation and processes -- nanomaterials: properties, preparation and processes -- contents -- preface -- theory of the magnetic pulsed compaction of nanosized powders -- abstract -- introduction -- 1. the nanopowders hardening laws and the radial compaction within the quasi-static conditions -- 2. regularities of dynamic processes of nanopowders radial compaction -- 3. the radial magnetic pulsed compaction within pronounced skin effect approximation -- 4. the î?- pinch theory taking into account the magnetic field diffusion
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|a The Dynamics of the Electric Circuit The Diffusion of the Magnetic Field -- Heating of the Turns, the Shell and the Rod -- Details of Numerical Calculations -- Comparison with Experiments -- Theoretical Calculations and the Discussion -- CONCLUSION -- REFERENCES -- TIO2 NANOCRYSTALS: PHASE SELECTIVE AND MORPHOLOGY CONTROLLABLE SYNTHESIS AND THEIR ENHANCED FUNCTIONALITY VIA DOPING -- ABSTRACT -- 1. INTRODUCTION -- 2. PHASE SELECTIVE AND MORPHOLOGY CONTROLLABLE SYNTHESIS OF TIO2 POLYMORPHS -- 2.1. Phase Controlled Synthesis via Hydrothermal Processing
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|a 2.2. Synthesis of Quasi-equiaxed Rutile Nanocrystals via Acid Hydrothermal Conversion of Degussa P25 2.3. Phase Structure and Morphology Controlled Synthesis under Near Ambient Conditions -- 3. DOPING TIO2 NANOCRYSTALS FOR ENHANCED FUNCTIONALITIES -- 3.1. Non-Metallic Doping of TiO2 for Enhanced Photocatalysis via Single Molecular Processing -- 3.2. Efficient Doping of TiO2 Nanocrystals via Radio-Frequency (RF) Thermal Plasma Processing -- 3.2.1. Chlorine doping for improved photocatalytic performances -- 3.2.2. Rare-earth doping for novel photoluminescent properties
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|a 3.2.3. Transition metal (Co2+) doping for room temperature ferromagnetismCONCLUSION -- ACKNOWLEDGMENT -- REFERENCES -- NANOPARTICLE SYNTHESIS BY THERMAL PLASMAS -- ABSTRACT -- 1. INTRODUCTION -- 2. CHARACTERISTICS OF THERMAL PLASMAS -- 2.1. Fundamental Processes in Thermal Plasmas -- 2.2. Induction Thermal Plasmas -- 2.3. DC Plasmas -- 3. Experimental Research of ITP-Aided Nanoparticle Synthesis -- 3.1. Intermetallic Compound and Alloy Nanoparticle -- 3.2. Ferrite Nanoparticle -- 3.3. Boride Nanoparticle -- 3.3.1. Thermodynamic Consideration
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|a 3.3.2. Experimental 3.3.3. Discussion -- 3.4. Silicide Nanoparticle -- 3.4.1. Experimental -- 3.5. Carbide Nanoparticle -- 3.5.1. Silicon Carbide -- 3.5.2. Tantalum Carbide -- 3.5.3. Tungsten Carbide -- 3.6. Nitride Nanoparticle -- 3.6.1. Titanium Nitride -- 3.6.2. Silicon Nitride -- 3.6.3. Aluminum Nitride -- 3.7. Oxide Nanoparticle -- 3.7.1. Experimental -- 4. MODELING OF ITP-AIDED NANOPARTICLE SYNTHESIS -- 4.1. Fundamental Mechanism -- 4.2. Model Description and Numerical Results -- 4.2.1. Induction Thermal Plasma
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|a eBooks on EBSCOhost
|b EBSCO eBook Subscription Academic Collection - Worldwide
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|a Nanostructured materials.
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|a Nanomatériaux.
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|a TECHNOLOGY & ENGINEERING
|x Material Science.
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|a Cabral, Vinicius.
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|a Silva, Renan,
|d 1965-
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|i Print version:
|t Nanomaterials.
|d New York : Nova Science Publishers, ©2010
|z 9781608766277
|w (DLC) 2009041996
|w (OCoLC)441192797
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