LEADER 00000cam a2200625Ka 4500 
001    ocn670430515 
003    OCoLC 
005    20160527040645.1 
006    m     o  d         
007    cr cnu---unuuu 
008    101018s2010    nyua    ob    001 0 eng d 
019    923657710 
020    9781617618031|q(electronic book) 
020    1617618039|q(electronic book) 
020    |z9781608766277 
020    |z1608766276 
035    (OCoLC)670430515|z(OCoLC)923657710 
040    N$T|beng|epn|cN$T|dOCLCQ|dYDXCP|dE7B|dOCLCF|dNLGGC|dEBLCP
       |dOCLCQ 
049    RIDW 
050  4 TA418.9.N35|bN3294 2010eb 
072  7 TEC|x021000|2bisacsh 
082 04 620.1/1|222 
090    TA418.9.N35|bN3294 2010eb 
245 00 Nanomaterials :|bproperties, preparation and processes /
       |cVinicius Cabral and Renan Silva, editors. 
264  1 New York :|bNova Science Publishers,|c[2010] 
264  4 |c©2010 
300    1 online resource (xvi, 412 pages) :|billustrations. 
336    text|btxt|2rdacontent 
337    computer|bc|2rdamedia 
338    online resource|bcr|2rdacarrier 
340    |gpolychrome|2rdacc 
347    text file|2rdaft 
490 1  Nanotechnology science and technology series 
504    Includes bibliographical references and index. 
505 0  ""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 "" 
505 8  ""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 "" 
505 8  ""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 "" 
505 8  ""3.2.3. Transition metal (Co2+) doping for room 
       temperature ferromagnetism""""CONCLUSION ""; 
       ""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 "" 
505 8  ""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 "" 
588 0  Print version record. 
590    eBooks on EBSCOhost|bEBSCO eBook Subscription Academic 
       Collection - North America 
650  0 Nanostructured materials.|0https://id.loc.gov/authorities/
       subjects/sh93000864 
650  7 Nanostructured materials.|2fast|0https://id.worldcat.org/
       fast/1032630 
655  4 Electronic books. 
700 1  Cabral, Vinicius.|0https://id.loc.gov/authorities/names/
       n2009069462 
700 1  Silva, Renan,|d1965-|0https://id.loc.gov/authorities/names
       /n2009069464 
776 08 |iPrint version:|tNanomaterials.|dNew York : Nova Science 
       Publishers, ©2010|z9781608766277|w(DLC)  2009041996
       |w(OCoLC)441192797 
830  0 Nanotechnology science and technology series.|0https://
       id.loc.gov/authorities/names/no2009109464 
856 40 |uhttps://rider.idm.oclc.org/login?url=http://
       search.ebscohost.com/login.aspx?direct=true&scope=site&
       db=nlebk&AN=340140|zOnline eBook. Access restricted to 
       current Rider University students, faculty, and staff. 
856 42 |3Instructions for reading/downloading this eBook|uhttp://
       guides.rider.edu/ebooks/ebsco 
901    MARCIVE 20231220 
948    |d20160616|cEBSCO|tebscoebooksacademic|lridw 
994    92|bRID