Nanoparticle technology handbook:
Gespeichert in:
| Format: | Buch |
|---|---|
| Sprache: | English |
| Veröffentlicht: |
Amsterdam [u.a.]
Elsevier
2007
|
| Ausgabe: | 1. ed. |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XXI, 622 S. |
| ISBN: | 9780444531223 |
Internformat
MARC
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| 245 | 1 | 0 | |a Nanoparticle technology handbook |c ed. by Masuo Hosokawa ... |
| 250 | |a 1. ed. | ||
| 264 | 1 | |a Amsterdam [u.a.] |b Elsevier |c 2007 | |
| 300 | |a XXI, 622 S. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 650 | 7 | |a Nanotecnologia |2 larpcal | |
| 650 | 4 | |a Nanoparticles | |
| 650 | 4 | |a Nanostructured materials | |
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| 700 | 1 | |a Hosokawa, Masuo |e Sonstige |4 oth | |
| 856 | 4 | 2 | |m HBZ Datenaustausch |q application/pdf |u http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016392456&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |3 Inhaltsverzeichnis |
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Datensatz im Suchindex
| _version_ | 1804137485715898369 |
|---|---|
| adam_text | Table of Contents
Preface
List of Contributors
From the Editors
FUNDAMENTALS
V
vii
xxi
Chapter 1 Basic properties and measuring methods of nanoparticles
1.1 Size effect and properties of
nanoparticles---------------------
1.1.1 Definition of nanoparticles
5
10
12
1.1.2 Features of nanoparticles 5
1.1.3 Evaluation of size of nanoparticles
1.1.4 Properties of nanoparticle and
size effect 6
1.1.5 Existing conditions of particles and
their properties 10
1.2 Particle size---------------------------------
1.2.1 Definition of particle size 10
1.2.2 Measuring methods 11
1.2.3 Key points in the measurements -
Reference particles for
calibration 11
1.3 Particle shape------------------------------
1.3.1 Two-dimensional particle projection
image 12
1.3.2 Three-dimensional particle image 12
1.3.3 Particle shape index using particle
diameter ratio 12
1.3.4 Particle shape expression by fractal
dimension 13
1.3.5 Particle shape analysis by Fourier
analysis 14
1.3.6 Particle shape analysis of
nanoparticle 14
1.4 Particle density —-----------------------------14
1.4.1 Density measurement of powders
composed of nanoparticles 14
1.4.2 Density measurement of individual
particles 15
1.5 Melting point, surface tension,
wettability-------------------------------------
1.5.1 Melting point 18
1.5.2 Surface tension IS
1.5.3 Wettability 19
1.6 Specific surface area and pore ------------
1.7 Composite structure-------------------------
1.7.1 Composite structure of
nanoparticle 23
1.7.2 Evaluation method of composite
structure using electron microscopy
1.7.3 Microstructure evaluation of
several types of nano composite
particles 25
1.8 Crystal structure-----------------------------
1.8.1 Particle size dependence of crystalline
phases of zirconia 2 ft
1.8.2 Size effect and crystalline phases of
ferroelectric materials 30
1.9 Surface characteristics----------------------
18
20
23
24
28
-32
36
-38
1.10 Mechanical property------------------
1.11 Electrical properties ------------------
1.11.1 Introduction 3H
1.11.2 Novel characterization method for the
dielectric property 39
1.11.3 LST relation 39
1.11.4 Measurement of the dielectric constant
of nanoparticles 40
1.12 Magnetic properties-------------------------42
1.12.1 Classification of magnetism 42
1.12.2 Magnetism of metal materials 43
XI
XII
TABLE OF CONTENTS
1.12.3 Magnetism of oxide material
1.12.4 Magnetic characteristics
of nanosized
materials 44
43 1.13 Optical property of nanoparticle-----
1.13.1 Band structure of nanoparticles
1.13.2 Measurement method of optical
properties of nanoparticles 47
-45
45
Chapter 2 Structural control of nanoparticles
2.1 Structure construction and
function adaptation of
nanoparticles-----------------------
2.1.1 Structures of nanoparticles
2.1.2 Hollow particles 52
2.1.3 Core-shell particles 52
2.1.4 Simple inorganic
nanoparticles 54
2.1.5 Simple organic nanoparticles
2.1.6 Summary 55
2.2 Particle size-------------------------
2.2.1 Gas-phase method
56
51
54
56
2.2.2 Liquid-phase method 58
2.2.3 Supercritical hydrothermal method
2.2.4 Solid-phase method 65
2.2.5 Grinding method 69
61
2.3 Particle shape----------
2.3.1 Gas-phase process
-71
71
2.3.2 Liquid-phase method 76
2.4 Composite structure —
2.4.1 Gas-phase method
79
87
91
2.4.2 Solution method 84
2.4.3 Supercritical approach
2.4.4 Mechanical processes
2.5 Pore structure--------------------------
2.5.1 Gas-phase method 94
2.5.2 Liquid-phase synthesis 100
2.6 Nanoparticle design for DDS-------
2.6.1 Drug delivery with nanoparticle
79
94
-105
105
2.6.2
2.6.3
106
2.6.4
Design of nano drug carrier
Design of nanoparticle surface
and application for DDS 108
Pharmaceutical nanotechnology 109
2.7 Nanotubes (CNT)----------------------------109
2.7.1 Production of MWNT by arc
discharge method 110
2.7.2 Production of SWNT by arc
discharge method 110
Chapter 3 Characteristics and behavior of nanoparticles and its dispersion systems
3.1 Introduction of nanoparticle dispersion and
aggregation behavior------------------------115
3.1.1 Surface interaction between
nanoparticles 115
3.1.2 Difficulty in nanoparticle dispersion
control based on DLVO theory 115
3.1.3 Difficulty in nanoparticle dispersion,
discussion based on the effect of particle
diameter and solid fraction on distance
between particle surface 116
3.1.4 Surface molecular-level structure of
nanoparticles [3] 117
3.1.5 Basic approach to control nanoparticle
dispersion behavior 118
3.2 Single nanoparticle motion in fluid
3.2.1 Single particle motion 119
3.2.2 Phoretic phenomena 121
3.3 Brownian diffusion -------------------
3.4
-119
Adsorption properties and
wettability of nanoparticle
surface -----------------------
-126
3.5 Interactions between particles ------
3.5.1 Interactions between particles in
gases and control of adhesion 129
3.5.2 Control of interactions between
particles in liquids 139
3.5.3 Characterization techniques for
interactions between particles 146
-127
129
TABLE OF CONTENTS
XIII
3.6 Aggregation and
dispersion, characterization
and control------------------------------------157 3.8
3.6.1 Aggregation and dispersion in
gas phase 157
3.6.2 Liquid phase 159
3.6.3 Dispersion in organic solvent
and polymer resin 163
3.7 Rheology of slurry---------------------------165
3.7.1 Fundamentals of suspension
rheology 165
3.7.2 Rheological property of nanoparticle
dispersed suspension 168
Simulation of colloidal dispersion
system-----------------------------------------
3.8.1 Space-time mapping of simulation
methods 770
3.8.2 Simulation methods in
nano/mesoscale 172
3.8.3 Recent simulation methods including
hydrodynamic interaction 174
3.8.4 Closing remark 775
169
Chapter 4 Control of nanostructure of materials
4.2.2
4.2.3
4.1 Assembly of nanoparticles and
functionalization------------------------------ 179
4.2 Nanoparticles arranged structures--------179
4.2.1 Photonic fractal 779
Nanoparticle patterning by
nanobiotechnology: Peptide 182
Preparation of ceramic films by
liquid-phase processing:
Electrophoresis 187
4.3 Nanopore structure--------------------------190
4.3.1 Microporous material: Zeolite 190
4.3.2 Preparation of nanoporous material
by dry processing 194
Ordered porous structures 196
Nanoporous materials (Titania
nanotubes) 199
4.4 Nanocomposite structure-------------
4.4.1 Catalyst microstructure 203
Percolation structure 206
4.3.3
4.3.4
203
4.4.2
4.4.3
4.4.4
Structure of filler orientation
in matrix 210
In situ particle polymerization
213
4.4.5 ECAP 216
4.4.6 Nanostructure control of alloy 220
4.5 Structure control of nanoparticle collectives
by sintering and bonding-------------------222
4.5.1 Sintering of nanoparticles 222
4.5.2 Low temperature cofired ceramics
(LTCC) 226
4.5.3 Nanostructure control of a joined
interface 230
4.5.4 Joining by FSW 233
4.5.5 Aerosol deposition method for
nanostructuring of crystal layer
and its applications 236
4.5.6 Suppression of particle growth in
sintering nanoparticles 242
4.5.7 Fabrication of nanoceramics
by colloidal processing 246
4.6 Self-assembly-----------------------------
4.6.1 Self-organization of nanoparticles
4.6.2 Assembling and patterning of
particles 256
4.6.3 Fabrication of organic/inorganic
mesoporous materials 262
-250
250
Chapter 5 Characterization methods for nanostructure of materials
5.1 Nanostructure and
function (characterization
of local
nanostructure)--------------
269
5.2 Crystal structure--------------
5.2.1 X-ray diffraction method
5.2.2 Small-angle X-ray
scattering 272
270
270
XIV
TABLE OF CONTENTS
5.2.3 Neutron diffraction 274
5.2.4 Raman scattering 277
5.3 Surface structure-----------------
5.3.1 AFM 279
5.3.2 STM 284
5.3.3 FT-IR 287
5.3.4 XPS 290
5.3.5 Wettability 294
5.4 Nanopore characterization-----
-279
297
5.4.1 Type of nitrogen isotherms
and pore characteristics implied 298
5.4.2 Micropore filling phenomenon and
PSD analysis 298
5.4.3 Capillary condensation phenomenon and
PSD analysis 299
5.4.4 Other methods of interest 302
5.5 Grain boundaries and interfaces---------303
5.5.1 The role of TEM 303
5.5.2 Analytical TEM (AEM) 306
5.5.3 Three-dimensional electron tomography
(3D-ET) 310
5.6 Evaluation methods for oxide
heterostructures------------------------------312
Chapter 6 Evaluation methods for properties of nanostructured body
6.1 Functionality of nanostructures and their
characteristic evaluation-------------------319
6.1.1 What are nanostructures? 319
6.1.2 Examples showing how the
functions of nanostructures are
performed 320
6.1.3 Functionality and characteristic
evaluation 322
6.2 Mechanical properties----------------------324
6.2.1 Strength, fracture toughness and
fatigue behavior 324
6.2.2 Elastic constants: hardness 326
6.2.3 Creep/superplasticity 329
6.2.4 Tribological properties 332
6.2.5 Nanoindentation 335
6.3 Thermophysical properties----------------336
6.3.1 Thermophysical properties
related to transfer and storage
of heat 336
6.3.2 Front-face heating/front-face
detection picosecond
thermoreflectance method 338
6.3.3 Picosecond thermoreflectance
method by rear face heating/
front-face detection 339
6.3.4 Nanosecond thermoreflectance
method 341
6.3.5 Thin film thermophysical
property reference material and
traceability 341
6.3.6 Summary 342
6.4 Electric properties---------------------------344
6.4.1 Dielectric properties 344
6.4.2 Electrical conduction properties 349
6.4.3 Thermoelectric properties 354
6.5 Electrochemical properties-----------------358
6.5.1 Electrode reaction 358
6.5.2 Characteristics of sensors 362
6.5.3 Electrochemical reactivity 366
6.6 Magnetic properties-------------------------370
6.6.1 Super paramagnetism 370
6.6.2 Material-specific discussion 370
6.7 Optical properties---------------------------372
6.7.1 Transparency of nanoparticle
6.7.2 Photonic crystal 375
6.8 Catalytic property-----------------
372
----------------------377
6.9 Properties of gas permeation and
separation membranes----------------------380
TABLE OF CONTENTS
XV
Chapter 7 Environmental and safety issues with nanoparticles
7.1 Introduction----------------------------------387
7.2 Nanoparticles and environment-----------387
7.2.1 Nanoparticles in atmospheric
environment 387
7.2.2 Ground water environments and
nanoparticles 389
7.2.3 Nanoparticles in exhaust gases 390
7.2.4 Nanoparticles in wastewater 392
7.2.5 Indoor environments and
nanoparticles 393
7.2.6 Industrial processes and
nanoparticles 396
7.3 Safety of nanoparticles---------------------400
7.3.1 Problems caused by nanoparticles 400
7.3.2 Health effects on nanoparticles 401
7.3.3 Safety assessment for the
nanoparticles 406
7.4 Removal of nanoparticles------------------410
7.4.1 Principle of particle removal 410
7.4.2 Removal of nanoparticles
suspended in gas 410
7.4.3 Removal of nanoparticles in
liquid 413
APPLICATIONS
1 Dispersion of fine silica particles using alkoxysilane and industrialization
423
1. Sol-gel hybrid 423
2. Molecular design 423
3. Unmeltable plastics: epoxy
resin hybrid 425
4. Tough resin: hybrid of the phenol
resin system 426
5. Soft silica hybrid: hybrid of the
urethane system 426
6. Cheap engineering plastics in
place for imide: hybrid of the
amideimide system 426
7. Imide useful for electroless plating:
hybrid of the imide system 427
2 Generation of metal nanoparticles using reactive plasma arc evaporation----------------------
1. Summary of the reactive plasma arc 3. The nanoparticles generation rate,
428
evaporation method 428
2. Nanoparticles by the reactive
plasma arc evaporation method
characteristics, and shape 429
Application of the nanoparticle
430
429
3 Sensing based on localized surface plasmon resonance in metallic nanoparticles --------------------432
1. Localized surface plasmon 432 2. Two sensing method using plasmon 432
4 Microelectronics packaging by metal nanoparticle pastes
1. Conductive paste technique and metal
nanoparticle paste 434
2. Low temperature firing and fine
electronic circuit pattern formation by
screen printing 435
434
3. Direct formation of the electronic circuit
pattern by inkjet printing 437
4. Application as the joining
materials 438
XVI
TABLE OF CONTENTS
5 A dye-sensitized solar cell utilizing metal nanoparticle -
1. What is a dye-sensitized
solar cell? 438
2. Enhancement of the absorption coefficient
of the ruthenium dye, with the silver
nanoparticle produced via vacuum
438
evaporation on the quartz
substrate 439
3. Enhancement of the absorption coefficient
of silver nanoparticle-ruthenium
dye within porous TiO2 440
6 Design of nanoparticles for oral delivery of peptide drugs-----------------
1. Particulate design and functions 443 2. Case studies
445
442
Formation of thick electronic ceramic films with bonding technique of crystalline
fine particles and their applications--------------------------------------------------------------
1. Aerosol deposition method 3. Applications of AD ceramic
(ADM) 450 films 451
2. Formation of thick electronic ceramic films
with ADM 450
450
8 Development and multi-functionalization of high-functional separation membranes -
1. Gas separation 453 2. Liquid separation 456
453
9 Development of polymer-clay nanocomposites by dispersion of particles into
polymer materials------------------
1. Nylon 6-clay hybrid 458
2. Synthesis and properties of
polypropylene-clay hybrid
459
458
3. Synthesis and properties of EPDM-clay
hybrid 459
4. Morphology control by polymers
with clay 459
10
11
Development of novel ferroelectric materials
1. Crystal structure of bismuth layer-
structured ferroelectrics (BLSFs) 460
2. Crystal growth and experimental
procedure 461
3. Layered structure, dielectric and leakage
current properties of BiT-BBTi
crystals 462
4. Giant polarization in BiT-BBTi
crystals 462
Development of new phosphors -
1. History of development of
nanophosphor 464
2. Properties of rare earth
nanophosphor 465
460
3. Development trend of new
nanophosphor 465
464
12 Zeolite membrane-----------
1. Characteristics 467
2. Synthesis 467
3. Separation properties of zeolite
membranes 469
467
TABLE OF CONTENTS xvii
13 Enhancement of the performance of insulating materials------------------------------------------------470
1. Withstand voltage characteristics 470 3. Thermal characteristics 473
2. Tracking-resistance and erosion-resistance
characteristics 472
14 Barium titanate nanoparticles synthesized under sub and supercritical
water conditions--------------------------------------------------------------------------------------------------473
1. Experiment for producing tetragonal 2. Selective production of tetragonal
BaTiOj nanoparticles by supercritical BaTiO, 474
hydrothermal synthesis 474
15 Ceramic filter for trapping diesel particles-----------------------------------------------------------------477
1. Production of PM 477 5. Functions and characteristics
2. Trapping of PM 478 ofDPF 480
3. Pressure loss 479 6. Future of filters for trapping diesel
4. Features of porous silicon carbide 480 particles 481
16 Nanoparticle formation of DNA (globule transformation)-----------------------------------------------481
1. Tolerance of DNA nanoparticles against 2. Micromanipulation of
mechanical stress 482 DNA nanoparticles 483
17 Addressing of nanoparticles by using DNA molecules----------------------------------------------------485
1. Stretching of DNA molecules 486 2. Addressing of nanoparticles 487
18 Development of high-performance electrochemical reactors---------------------------------------------489
1. Environmental purification by 3. Development of the electrochemical
electrochemical reactors 489 reactors for simultaneous purification of
2. NOX decomposition in the exhaust gas with NOr/PM 492
electrochemical reactors 489
19 Dendrimers and their application to organic electronics devices---------------------------------------494
1. Synthesis and structure of 2. Metal assembling property of
dendrimer 494 dendrimer 496
3. Application to electronic devices 496
20 Electrical conductive CNT dispersed Si,N4 ceramics-----------------------------------------------------498
21 Development of functional skincare cosmetics using biodegradable PLGA nanospheres----------501
1. Nanocosmetics that whiten skin and 3. Functional cosmetics using PLGA
eliminate wrinkles 501 nanospheres 504
2. Evaluation of the cutaneous permeability
of PLGA nanospheres and their functional
effect 501
XVIII
TABLE OF CONTENTS
22
23
24
25
26
Development of photonic crystals based on nanoparticle assembly--------------------
1. Nanoparticle assembly 2. Fabrication of photonic crystals by
technique 506 nanoparticle assembly technique
506
507
Liquid-crystalline inorganic nano and fine particles
1. Organic liquid crystals and lyotropic
liquid-crystalline inorganic fine
particles 509
----------------------------------------------------509
2. Development of organic-inorganic hybrid
liquid crystals 570
3. Summary and prospect 514
Closely packed colloidal crystal assembled with nanoparticles and
its application for smart materials with tunable structural color —
1. Closely packed colloidal crystal
films 516
2. Structural color of colloidal crystal and its
tuning mechanism 517
515
3. Tunable structural color by swelling with
liquid 5/8
4. Tunable structural color by applying
mechanical stress 519
5. Summary and outlook 519
Development of new cosmetics based on nanoparticles —
1. Use of nanoparticles 521 3.
2. Use as compound particles 524
521
Future development 526
Dispersion control of A12O3 nanoparticles in ethanol
1. Effect of molecular weight of PEI on
nanoparticle suspension viscosity 527
2. Relationship between molecular size of
PEI and suspension viscosity 528
527
3. Surface interaction between A12O3
nanoparticles using nanocolloidal
probe AFM 528
4. Action mechanism of polymer dispersant
on A12O3 nanoparticle suspension 529
27 Development of the thermoresponsive magnetic nanoparticle and
its deployment in the biotechnology field —
1. Magnetic nanoparticle material 531
2. What is a thermoresponsive
polymer? 531
3. Thermoresponsive magnetic
nanoparticles 532
----------------------------------------------------531
4. Application examples of the
thermoresponsive magnetic nanoparticles
to the biotechnology field 533
5. Future perspective 537
28 Development of fuel cells-----------
1. Development task of fuel cells
539
29 Delivery to the brain------------------
1. Surface modification to improve
the nanoparticle distribution
in the brain 543
538
2. Development of high-performance solid
oxide fuel cells using nanoparticle
technology 540
----------------------------------------------------543
Effect of administration route on the brain
distribution 544
Perspective of brain targeting with
nanoparticles 546
TABLE OF CONTENTS
XIX
30 Nozzle-free inkjet technology
1. Principle of nozzle-free inkjet technology
and outline of developed system 547
546
2. Formation of slurry using nozzle-free
inkjet technology 549
31 Development of exhaust catalyst-----
1. Supported metal catalyst 550
2. Oxygen storage capacity (OSC)
of catalyst 551
550
3. Improvement of OSC of catalyst
4. Improvement of thermal resistance
of catalyst 553
551
32 Development of optical memory using semiconductor nanoparticles
555
1. Fluorescence characteristics of
semiconductor nanoparticles 555
2. Optical memory effect of semiconductor
nanoparticle thin films 556
3. Methods of preparing and evaluating CdSe
thin films 556
4. Dependency of intensity of fluorescence on
the excitation light intensity 556
5. Future topics 557
33 Development of bright phosphors using glasses incorporating
semiconductor nanoparticles--------------------------------------------------------------------------
1. Syntheses of highly photoluminescent 2. Preparation of glass phosphors
558
semiconductor nanoparticles by an aqueous
solution method 559
incorporating semiconductor nanoparticles
by a sol-gel method 559
34 Development of photocatalyst inserted into surface of porous aluminosilicate---------------
1. Structure of TiO,-aluminosilicate 3. Photoenduarance of paper with
complex 562
2. Photocatalysis of TiO,-aluminosilicate
complex 562
562
TiOv-aluminosilicate complex 564
35 AC overhead transmission line audible-noise reduction measures using
surface improvement--------------------------------------------
1. Audible noise of AC overhead transmission
lines 566
2. Wetting property of power lines 566
3. Preparation of test power lines 567
566
4. Features of titanium oxide thermal-sprayed
films 568
5. Audible-noise measurement 568
36 Development of a high-performance secondary battery by controlling
the surface structure------------------------------------------------------------
1. Anode of a nickel hydrogen battery
2. Cathode of the nickel hydrogen
battery 572
570
571 3. Cathode of lithium ion battery 572
4. Anode of the lithium ion battery 573
37 Pinpoint drug and gene delivery-----------
1. Bio-nanocapsules (BNC) 575
2. Potential applications of BNC 576
3. Assignment
4. Conclusion
577
578
¦575
XX
TABLE OF CONTENTS
38
39
Expression of optical function by nanostructure using femtosecond
laser processing---------------------------------------------------------------
578
1.
Space selective valence state manipulation
of rare earth ions inside glasses 578
Precipitation control of gold nanoparticles
inside transparent materials by a
femtosecond laser 579
Instantaneous nanofoaming method for fabrication of closed-porosity
silica particle----------------------------------------------------------------------
3. Nanograting fabrication 581
583
40 Evaluation and applications of dispersing carbon nanotube in the polymers -
588
1. Carbon nanotube 588
2. Fracture model of agglomerates of carbon
nanotube 588
3. Dispersion of CNT by an extruder 588
4. Dispersion of composites and
its evaluation 590
5. Relationship between the agglomerate
fraction Ar and composite
properties 590
6. Percolation 597
7. Development of CNT composite resin
materials 592
41 Surface modification of inorganic nanoparticles by organic functional groups-----------------------593
1. Surface-modified noble metal 3. Hybridization of inorganic nanoparticles
nanoparticles 593 with biomolecules 595
2. Organic modification of metal oxide
nanoparticles 593
42 Fabrication technique of organic nanocrystals and their optical properties
43
and materialization--------------------
1. The organic compounds used for
nanocrystallization 596
2. Fabrication techniques of organic
nanocrystals 596
596
3. Size-dependence of optical properties for
organic nanocrystals 599
4. Orientation control of dispersed organic
nanocrystals by external field 600
Bio-imaging with quantum dots -
1. Developments of quantum dots
2. Development of bio-imaging
601
607
602
3. Bio-imaging and quantum dots 602
4. Quantum dots label for the
antibody 603
5. In vivo imaging of the quantum dots
stained cell: the localization
in organs 603
6. Observation of the localization from
outside of the body 605
44 Application of quantum dots for bio-medical engineering--------------------------------------
1. Application for laboratory test 606 2. Diagnosis by imaging analysis
606
607
Subject Index
609
|
| adam_txt |
Table of Contents
Preface
List of Contributors
From the Editors
FUNDAMENTALS
V
vii
xxi
Chapter 1 Basic properties and measuring methods of nanoparticles
1.1 Size effect and properties of
nanoparticles---------------------
1.1.1 Definition of nanoparticles
5
10
12
1.1.2 Features of nanoparticles 5
1.1.3 Evaluation of size of nanoparticles
1.1.4 Properties of nanoparticle and
size effect 6
1.1.5 Existing conditions of particles and
their properties 10
1.2 Particle size---------------------------------
1.2.1 Definition of particle size 10
1.2.2 Measuring methods 11
1.2.3 Key points in the measurements -
Reference particles for
calibration 11
1.3 Particle shape------------------------------
1.3.1 Two-dimensional particle projection
image 12
1.3.2 Three-dimensional particle image 12
1.3.3 Particle shape index using particle
diameter ratio 12
1.3.4 Particle shape expression by fractal
dimension 13
1.3.5 Particle shape analysis by Fourier
analysis 14
1.3.6 Particle shape analysis of
nanoparticle 14
1.4 Particle density —-----------------------------14
1.4.1 Density measurement of powders
composed of nanoparticles 14
1.4.2 Density measurement of individual
particles 15
1.5 Melting point, surface tension,
wettability-------------------------------------
1.5.1 Melting point 18
1.5.2 Surface tension IS
1.5.3 Wettability 19
1.6 Specific surface area and pore ------------
1.7 Composite structure-------------------------
1.7.1 Composite structure of
nanoparticle 23
1.7.2 Evaluation method of composite
structure using electron microscopy
1.7.3 Microstructure evaluation of
several types of nano composite
particles 25
1.8 Crystal structure-----------------------------
1.8.1 Particle size dependence of crystalline
phases of zirconia 2 ft
1.8.2 Size effect and crystalline phases of
ferroelectric materials 30
1.9 Surface characteristics----------------------
18
20
23
24
28
-32
36
-38
1.10 Mechanical property------------------
1.11 Electrical properties ------------------
1.11.1 Introduction 3H
1.11.2 Novel characterization method for the
dielectric property 39
1.11.3 LST relation 39
1.11.4 Measurement of the dielectric constant
of nanoparticles 40
1.12 Magnetic properties-------------------------42
1.12.1 Classification of magnetism 42
1.12.2 Magnetism of metal materials 43
XI
XII
TABLE OF CONTENTS
1.12.3 Magnetism of oxide material
1.12.4 Magnetic characteristics
of nanosized
materials 44
43 1.13 Optical property of nanoparticle-----
1.13.1 Band structure of nanoparticles
1.13.2 Measurement method of optical
properties of nanoparticles 47
-45
45
Chapter 2 Structural control of nanoparticles
2.1 Structure construction and
function adaptation of
nanoparticles-----------------------
2.1.1 Structures of nanoparticles
2.1.2 Hollow particles 52
2.1.3 Core-shell particles 52
2.1.4 Simple inorganic
nanoparticles 54
2.1.5 Simple organic nanoparticles
2.1.6 Summary 55
2.2 Particle size-------------------------
2.2.1 Gas-phase method
56
51
54
56
2.2.2 Liquid-phase method 58
2.2.3 Supercritical hydrothermal method
2.2.4 Solid-phase method 65
2.2.5 Grinding method 69
61
2.3 Particle shape----------
2.3.1 Gas-phase process
-71
71
2.3.2 Liquid-phase method 76
2.4 Composite structure —
2.4.1 Gas-phase method
79
87
91
2.4.2 Solution method 84
2.4.3 Supercritical approach
2.4.4 Mechanical processes
2.5 Pore structure--------------------------
2.5.1 Gas-phase method 94
2.5.2 Liquid-phase synthesis 100
2.6 Nanoparticle design for DDS-------
2.6.1 Drug delivery with nanoparticle
79
94
-105
105
2.6.2
2.6.3
106
2.6.4
Design of nano drug carrier
Design of nanoparticle surface
and application for DDS 108
Pharmaceutical nanotechnology 109
2.7 Nanotubes (CNT)----------------------------109
2.7.1 Production of MWNT by arc
discharge method 110
2.7.2 Production of SWNT by arc
discharge method 110
Chapter 3 Characteristics and behavior of nanoparticles and its dispersion systems
3.1 Introduction of nanoparticle dispersion and
aggregation behavior------------------------115
3.1.1 Surface interaction between
nanoparticles 115
3.1.2 Difficulty in nanoparticle dispersion
control based on DLVO theory 115
3.1.3 Difficulty in nanoparticle dispersion,
discussion based on the effect of particle
diameter and solid fraction on distance
between particle surface 116
3.1.4 Surface molecular-level structure of
nanoparticles [3] 117
3.1.5 Basic approach to control nanoparticle
dispersion behavior 118
3.2 Single nanoparticle motion in fluid
3.2.1 Single particle motion 119
3.2.2 Phoretic phenomena 121
3.3 Brownian diffusion -------------------
3.4
-119
Adsorption properties and
wettability of nanoparticle
surface -----------------------
-126
3.5 Interactions between particles ------
3.5.1 Interactions between particles in
gases and control of adhesion 129
3.5.2 Control of interactions between
particles in liquids 139
3.5.3 Characterization techniques for
interactions between particles 146
-127
129
TABLE OF CONTENTS
XIII
3.6 Aggregation and
dispersion, characterization
and control------------------------------------157 3.8
3.6.1 Aggregation and dispersion in
gas phase 157
3.6.2 Liquid phase 159
3.6.3 Dispersion in organic solvent
and polymer resin 163
3.7 Rheology of slurry---------------------------165
3.7.1 Fundamentals of suspension
rheology 165
3.7.2 Rheological property of nanoparticle
dispersed suspension 168
Simulation of colloidal dispersion
system-----------------------------------------
3.8.1 Space-time mapping of simulation
methods 770
3.8.2 Simulation methods in
nano/mesoscale 172
3.8.3 Recent simulation methods including
hydrodynamic interaction 174
3.8.4 Closing remark 775
169
Chapter 4 Control of nanostructure of materials
4.2.2
4.2.3
4.1 Assembly of nanoparticles and
functionalization------------------------------ 179
4.2 Nanoparticles arranged structures--------179
4.2.1 Photonic fractal 779
Nanoparticle patterning by
nanobiotechnology: Peptide 182
Preparation of ceramic films by
liquid-phase processing:
Electrophoresis 187
4.3 Nanopore structure--------------------------190
4.3.1 Microporous material: Zeolite 190
4.3.2 Preparation of nanoporous material
by dry processing 194
Ordered porous structures 196
Nanoporous materials (Titania
nanotubes) 199
4.4 Nanocomposite structure-------------
4.4.1 Catalyst microstructure 203
Percolation structure 206
4.3.3
4.3.4
203
4.4.2
4.4.3
4.4.4
Structure of filler orientation
in matrix 210
In situ particle polymerization
213
4.4.5 ECAP 216
4.4.6 Nanostructure control of alloy 220
4.5 Structure control of nanoparticle collectives
by sintering and bonding-------------------222
4.5.1 Sintering of nanoparticles 222
4.5.2 Low temperature cofired ceramics
(LTCC) 226
4.5.3 Nanostructure control of a joined
interface 230
4.5.4 Joining by FSW 233
4.5.5 Aerosol deposition method for
nanostructuring of crystal layer
and its applications 236
4.5.6 Suppression of particle growth in
sintering nanoparticles 242
4.5.7 Fabrication of nanoceramics
by colloidal processing 246
4.6 Self-assembly-----------------------------
4.6.1 Self-organization of nanoparticles
4.6.2 Assembling and patterning of
particles 256
4.6.3 Fabrication of organic/inorganic
mesoporous materials 262
-250
250
Chapter 5 Characterization methods for nanostructure of materials
5.1 Nanostructure and
function (characterization
of local
nanostructure)--------------
269
5.2 Crystal structure--------------
5.2.1 X-ray diffraction method
5.2.2 Small-angle X-ray
scattering 272
270
270
XIV
TABLE OF CONTENTS
5.2.3 Neutron diffraction 274
5.2.4 Raman scattering 277
5.3 Surface structure-----------------
5.3.1 AFM 279
5.3.2 STM 284
5.3.3 FT-IR 287
5.3.4 XPS 290
5.3.5 Wettability 294
5.4 Nanopore characterization-----
-279
297
5.4.1 Type of nitrogen isotherms
and pore characteristics implied 298
5.4.2 Micropore filling phenomenon and
PSD analysis 298
5.4.3 Capillary condensation phenomenon and
PSD analysis 299
5.4.4 Other methods of interest 302
5.5 Grain boundaries and interfaces---------303
5.5.1 The role of TEM 303
5.5.2 Analytical TEM (AEM) 306
5.5.3 Three-dimensional electron tomography
(3D-ET) 310
5.6 Evaluation methods for oxide
heterostructures------------------------------312
Chapter 6 Evaluation methods for properties of nanostructured body
6.1 Functionality of nanostructures and their
characteristic evaluation-------------------319
6.1.1 What are nanostructures? 319
6.1.2 Examples showing how the
functions of nanostructures are
performed 320
6.1.3 Functionality and characteristic
evaluation 322
6.2 Mechanical properties----------------------324
6.2.1 Strength, fracture toughness and
fatigue behavior 324
6.2.2 Elastic constants: hardness 326
6.2.3 Creep/superplasticity 329
6.2.4 Tribological properties 332
6.2.5 Nanoindentation 335
6.3 Thermophysical properties----------------336
6.3.1 Thermophysical properties
related to transfer and storage
of heat 336
6.3.2 Front-face heating/front-face
detection picosecond
thermoreflectance method 338
6.3.3 Picosecond thermoreflectance
method by rear face heating/
front-face detection 339
6.3.4 Nanosecond thermoreflectance
method 341
6.3.5 Thin film thermophysical
property reference material and
traceability 341
6.3.6 Summary 342
6.4 Electric properties---------------------------344
6.4.1 Dielectric properties 344
6.4.2 Electrical conduction properties 349
6.4.3 Thermoelectric properties 354
6.5 Electrochemical properties-----------------358
6.5.1 Electrode reaction 358
6.5.2 Characteristics of sensors 362
6.5.3 Electrochemical reactivity 366
6.6 Magnetic properties-------------------------370
6.6.1 Super paramagnetism 370
6.6.2 Material-specific discussion 370
6.7 Optical properties---------------------------372
6.7.1 Transparency of nanoparticle
6.7.2 Photonic crystal 375
6.8 Catalytic property-----------------
372
----------------------377
6.9 Properties of gas permeation and
separation membranes----------------------380
TABLE OF CONTENTS
XV
Chapter 7 Environmental and safety issues with nanoparticles
7.1 Introduction----------------------------------387
7.2 Nanoparticles and environment-----------387
7.2.1 Nanoparticles in atmospheric
environment 387
7.2.2 Ground water environments and
nanoparticles 389
7.2.3 Nanoparticles in exhaust gases 390
7.2.4 Nanoparticles in wastewater 392
7.2.5 Indoor environments and
nanoparticles 393
7.2.6 Industrial processes and
nanoparticles 396
7.3 Safety of nanoparticles---------------------400
7.3.1 Problems caused by nanoparticles 400
7.3.2 Health effects on nanoparticles 401
7.3.3 Safety assessment for the
nanoparticles 406
7.4 Removal of nanoparticles------------------410
7.4.1 Principle of particle removal 410
7.4.2 Removal of nanoparticles
suspended in gas 410
7.4.3 Removal of nanoparticles in
liquid 413
APPLICATIONS
1 Dispersion of fine silica particles using alkoxysilane and industrialization
423
1. Sol-gel hybrid 423
2. Molecular design 423
3. Unmeltable plastics: epoxy
resin hybrid 425
4. Tough resin: hybrid of the phenol
resin system 426
5. Soft silica hybrid: hybrid of the
urethane system 426
6. Cheap engineering plastics in
place for imide: hybrid of the
amideimide system 426
7. Imide useful for electroless plating:
hybrid of the imide system 427
2 Generation of metal nanoparticles using reactive plasma arc evaporation----------------------
1. Summary of the reactive plasma arc 3. The nanoparticles generation rate,
428
evaporation method 428
2. Nanoparticles by the reactive
plasma arc evaporation method
characteristics, and shape 429
Application of the nanoparticle
430
429
3 Sensing based on localized surface plasmon resonance in metallic nanoparticles --------------------432
1. Localized surface plasmon 432 2. Two sensing method using plasmon 432
4 Microelectronics packaging by metal nanoparticle pastes
1. Conductive paste technique and metal
nanoparticle paste 434
2. Low temperature firing and fine
electronic circuit pattern formation by
screen printing 435
434
3. Direct formation of the electronic circuit
pattern by inkjet printing 437
4. Application as the joining
materials 438
XVI
TABLE OF CONTENTS
5 A dye-sensitized solar cell utilizing metal nanoparticle -
1. What is a dye-sensitized
solar cell? 438
2. Enhancement of the absorption coefficient
of the ruthenium dye, with the silver
nanoparticle produced via vacuum
438
evaporation on the quartz
substrate 439
3. Enhancement of the absorption coefficient
of silver nanoparticle-ruthenium
dye within porous TiO2 440
6 Design of nanoparticles for oral delivery of peptide drugs-----------------
1. Particulate design and functions 443 2. Case studies
445
442
Formation of thick electronic ceramic films with bonding technique of crystalline
fine particles and their applications--------------------------------------------------------------
1. Aerosol deposition method 3. Applications of AD ceramic
(ADM) 450 films 451
2. Formation of thick electronic ceramic films
with ADM 450
450
8 Development and multi-functionalization of high-functional separation membranes -
1. Gas separation 453 2. Liquid separation 456
453
9 Development of polymer-clay nanocomposites by dispersion of particles into
polymer materials------------------
1. Nylon 6-clay hybrid 458
2. Synthesis and properties of
polypropylene-clay hybrid
459
458
3. Synthesis and properties of EPDM-clay
hybrid 459
4. Morphology control by polymers
with clay 459
10
11
Development of novel ferroelectric materials
1. Crystal structure of bismuth layer-
structured ferroelectrics (BLSFs) 460
2. Crystal growth and experimental
procedure 461
3. Layered structure, dielectric and leakage
current properties of BiT-BBTi
crystals 462
4. Giant polarization in BiT-BBTi
crystals 462
Development of new phosphors -
1. History of development of
nanophosphor 464
2. Properties of rare earth
nanophosphor 465
460
3. Development trend of new
nanophosphor 465
464
12 Zeolite membrane-----------
1. Characteristics 467
2. Synthesis 467
3. Separation properties of zeolite
membranes 469
467
TABLE OF CONTENTS xvii
13 Enhancement of the performance of insulating materials------------------------------------------------470
1. Withstand voltage characteristics 470 3. Thermal characteristics 473
2. Tracking-resistance and erosion-resistance
characteristics 472
14 Barium titanate nanoparticles synthesized under sub and supercritical
water conditions--------------------------------------------------------------------------------------------------473
1. Experiment for producing tetragonal 2. Selective production of tetragonal
BaTiOj nanoparticles by supercritical BaTiO, 474
hydrothermal synthesis 474
15 Ceramic filter for trapping diesel particles-----------------------------------------------------------------477
1. Production of PM 477 5. Functions and characteristics
2. Trapping of PM 478 ofDPF 480
3. Pressure loss 479 6. Future of filters for trapping diesel
4. Features of porous silicon carbide 480 particles 481
16 Nanoparticle formation of DNA (globule transformation)-----------------------------------------------481
1. Tolerance of DNA nanoparticles against 2. Micromanipulation of
mechanical stress 482 DNA nanoparticles 483
17 Addressing of nanoparticles by using DNA molecules----------------------------------------------------485
1. Stretching of DNA molecules 486 2. Addressing of nanoparticles 487
18 Development of high-performance electrochemical reactors---------------------------------------------489
1. Environmental purification by 3. Development of the electrochemical
electrochemical reactors 489 reactors for simultaneous purification of
2. NOX decomposition in the exhaust gas with NOr/PM 492
electrochemical reactors 489
19 Dendrimers and their application to organic electronics devices---------------------------------------494
1. Synthesis and structure of 2. Metal assembling property of
dendrimer 494 dendrimer 496
3. Application to electronic devices 496
20 Electrical conductive CNT dispersed Si,N4 ceramics-----------------------------------------------------498
21 Development of functional skincare cosmetics using biodegradable PLGA nanospheres----------501
1. Nanocosmetics that whiten skin and 3. Functional cosmetics using PLGA
eliminate wrinkles 501 nanospheres 504
2. Evaluation of the cutaneous permeability
of PLGA nanospheres and their functional
effect 501
XVIII
TABLE OF CONTENTS
22
23
24
25
26
Development of photonic crystals based on nanoparticle assembly--------------------
1. Nanoparticle assembly 2. Fabrication of photonic crystals by
technique 506 nanoparticle assembly technique
506
507
Liquid-crystalline inorganic nano and fine particles
1. Organic liquid crystals and lyotropic
liquid-crystalline inorganic fine
particles 509
----------------------------------------------------509
2. Development of organic-inorganic hybrid
liquid crystals 570
3. Summary and prospect 514
Closely packed colloidal crystal assembled with nanoparticles and
its application for smart materials with tunable structural color —
1. Closely packed colloidal crystal
films 516
2. Structural color of colloidal crystal and its
tuning mechanism 517
515
3. Tunable structural color by swelling with
liquid 5/8
4. Tunable structural color by applying
mechanical stress 519
5. Summary and outlook 519
Development of new cosmetics based on nanoparticles —
1. Use of nanoparticles 521 3.
2. Use as compound particles 524
521
Future development 526
Dispersion control of A12O3 nanoparticles in ethanol
1. Effect of molecular weight of PEI on
nanoparticle suspension viscosity 527
2. Relationship between molecular size of
PEI and suspension viscosity 528
527
3. Surface interaction between A12O3
nanoparticles using nanocolloidal
probe AFM 528
4. Action mechanism of polymer dispersant
on A12O3 nanoparticle suspension 529
27 Development of the thermoresponsive magnetic nanoparticle and
its deployment in the biotechnology field —
1. Magnetic nanoparticle material 531
2. What is a thermoresponsive
polymer? 531
3. Thermoresponsive magnetic
nanoparticles 532
----------------------------------------------------531
4. Application examples of the
thermoresponsive magnetic nanoparticles
to the biotechnology field 533
5. Future perspective 537
28 Development of fuel cells-----------
1. Development task of fuel cells
539
29 Delivery to the brain------------------
1. Surface modification to improve
the nanoparticle distribution
in the brain 543
538
2. Development of high-performance solid
oxide fuel cells using nanoparticle
technology 540
----------------------------------------------------543
Effect of administration route on the brain
distribution 544
Perspective of brain targeting with
nanoparticles 546
TABLE OF CONTENTS
XIX
30 Nozzle-free inkjet technology
1. Principle of nozzle-free inkjet technology
and outline of developed system 547
546
2. Formation of slurry using nozzle-free
inkjet technology 549
31 Development of exhaust catalyst-----
1. Supported metal catalyst 550
2. Oxygen storage capacity (OSC)
of catalyst 551
550
3. Improvement of OSC of catalyst
4. Improvement of thermal resistance
of catalyst 553
551
32 Development of optical memory using semiconductor nanoparticles
555
1. Fluorescence characteristics of
semiconductor nanoparticles 555
2. Optical memory effect of semiconductor
nanoparticle thin films 556
3. Methods of preparing and evaluating CdSe
thin films 556
4. Dependency of intensity of fluorescence on
the excitation light intensity 556
5. Future topics 557
33 Development of bright phosphors using glasses incorporating
semiconductor nanoparticles--------------------------------------------------------------------------
1. Syntheses of highly photoluminescent 2. Preparation of glass phosphors
558
semiconductor nanoparticles by an aqueous
solution method 559
incorporating semiconductor nanoparticles
by a sol-gel method 559
34 Development of photocatalyst inserted into surface of porous aluminosilicate---------------
1. Structure of TiO,-aluminosilicate 3. Photoenduarance of paper with
complex 562
2. Photocatalysis of TiO,-aluminosilicate
complex 562
562
TiOv-aluminosilicate complex 564
35 AC overhead transmission line audible-noise reduction measures using
surface improvement--------------------------------------------
1. Audible noise of AC overhead transmission
lines 566
2. Wetting property of power lines 566
3. Preparation of test power lines 567
566
4. Features of titanium oxide thermal-sprayed
films 568
5. Audible-noise measurement 568
36 Development of a high-performance secondary battery by controlling
the surface structure------------------------------------------------------------
1. Anode of a nickel hydrogen battery
2. Cathode of the nickel hydrogen
battery 572
570
571 3. Cathode of lithium ion battery 572
4. Anode of the lithium ion battery 573
37 Pinpoint drug and gene delivery-----------
1. Bio-nanocapsules (BNC) 575
2. Potential applications of BNC 576
3. Assignment
4. Conclusion
577
578
¦575
XX
TABLE OF CONTENTS
38
39
Expression of optical function by nanostructure using femtosecond
laser processing---------------------------------------------------------------
578
1.
Space selective valence state manipulation
of rare earth ions inside glasses 578
Precipitation control of gold nanoparticles
inside transparent materials by a
femtosecond laser 579
Instantaneous nanofoaming method for fabrication of closed-porosity
silica particle----------------------------------------------------------------------
3. Nanograting fabrication 581
583
40 Evaluation and applications of dispersing carbon nanotube in the polymers -
588
1. Carbon nanotube 588
2. Fracture model of agglomerates of carbon
nanotube 588
3. Dispersion of CNT by an extruder 588
4. Dispersion of composites and
its evaluation 590
5. Relationship between the agglomerate
fraction Ar and composite
properties 590
6. Percolation 597
7. Development of CNT composite resin
materials 592
41 Surface modification of inorganic nanoparticles by organic functional groups-----------------------593
1. Surface-modified noble metal 3. Hybridization of inorganic nanoparticles
nanoparticles 593 with biomolecules 595
2. Organic modification of metal oxide
nanoparticles 593
42 Fabrication technique of organic nanocrystals and their optical properties
43
and materialization--------------------
1. The organic compounds used for
nanocrystallization 596
2. Fabrication techniques of organic
nanocrystals 596
596
3. Size-dependence of optical properties for
organic nanocrystals 599
4. Orientation control of dispersed organic
nanocrystals by external field 600
Bio-imaging with quantum dots -
1. Developments of quantum dots
2. Development of bio-imaging
601
607
602
3. Bio-imaging and quantum dots 602
4. Quantum dots label for the
antibody 603
5. In vivo imaging of the quantum dots
stained cell: the localization
in organs 603
6. Observation of the localization from
outside of the body 605
44 Application of quantum dots for bio-medical engineering--------------------------------------
1. Application for laboratory test 606 2. Diagnosis by imaging analysis
606
607
Subject Index
609 |
| any_adam_object | 1 |
| any_adam_object_boolean | 1 |
| building | Verbundindex |
| bvnumber | BV023206310 |
| callnumber-first | T - Technology |
| callnumber-label | TA418 |
| callnumber-raw | TA418.78 TA418.9.N35 |
| callnumber-search | TA418.78 TA418.9.N35 |
| callnumber-sort | TA 3418.78 |
| callnumber-subject | TA - General and Civil Engineering |
| classification_rvk | VE 9850 ZM 7090 ZN 3700 |
| ctrlnum | (OCoLC)84612012 (DE-599)GBV546432670 |
| dewey-full | 620.5 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 620 - Engineering and allied operations |
| dewey-raw | 620.5 |
| dewey-search | 620.5 |
| dewey-sort | 3620.5 |
| dewey-tens | 620 - Engineering and allied operations |
| discipline | Chemie / Pharmazie Werkstoffwissenschaften / Fertigungstechnik Elektrotechnik / Elektronik / Nachrichtentechnik |
| discipline_str_mv | Chemie / Pharmazie Werkstoffwissenschaften / Fertigungstechnik Elektrotechnik / Elektronik / Nachrichtentechnik |
| edition | 1. ed. |
| format | Book |
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| genre_facet | Aufsatzsammlung |
| id | DE-604.BV023206310 |
| illustrated | Not Illustrated |
| index_date | 2024-07-02T20:10:11Z |
| indexdate | 2024-07-09T21:13:03Z |
| institution | BVB |
| isbn | 9780444531223 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-016392456 |
| oclc_num | 84612012 |
| open_access_boolean | |
| owner | DE-29T DE-83 DE-11 DE-92 |
| owner_facet | DE-29T DE-83 DE-11 DE-92 |
| physical | XXI, 622 S. |
| publishDate | 2007 |
| publishDateSearch | 2007 |
| publishDateSort | 2007 |
| publisher | Elsevier |
| record_format | marc |
| spelling | Nanoparticle technology handbook ed. by Masuo Hosokawa ... 1. ed. Amsterdam [u.a.] Elsevier 2007 XXI, 622 S. txt rdacontent n rdamedia nc rdacarrier Nanotecnologia larpcal Nanoparticles Nanostructured materials Nanotechnologie (DE-588)4327470-5 gnd rswk-swf Nanostrukturiertes Material (DE-588)4342626-8 gnd rswk-swf Nanopartikel (DE-588)4333369-2 gnd rswk-swf (DE-588)4143413-4 Aufsatzsammlung gnd-content Nanopartikel (DE-588)4333369-2 s Nanotechnologie (DE-588)4327470-5 s DE-604 Nanostrukturiertes Material (DE-588)4342626-8 s 1\p DE-604 Hosokawa, Masuo Sonstige oth HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016392456&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk |
| spellingShingle | Nanoparticle technology handbook Nanotecnologia larpcal Nanoparticles Nanostructured materials Nanotechnologie (DE-588)4327470-5 gnd Nanostrukturiertes Material (DE-588)4342626-8 gnd Nanopartikel (DE-588)4333369-2 gnd |
| subject_GND | (DE-588)4327470-5 (DE-588)4342626-8 (DE-588)4333369-2 (DE-588)4143413-4 |
| title | Nanoparticle technology handbook |
| title_auth | Nanoparticle technology handbook |
| title_exact_search | Nanoparticle technology handbook |
| title_exact_search_txtP | Nanoparticle technology handbook |
| title_full | Nanoparticle technology handbook ed. by Masuo Hosokawa ... |
| title_fullStr | Nanoparticle technology handbook ed. by Masuo Hosokawa ... |
| title_full_unstemmed | Nanoparticle technology handbook ed. by Masuo Hosokawa ... |
| title_short | Nanoparticle technology handbook |
| title_sort | nanoparticle technology handbook |
| topic | Nanotecnologia larpcal Nanoparticles Nanostructured materials Nanotechnologie (DE-588)4327470-5 gnd Nanostrukturiertes Material (DE-588)4342626-8 gnd Nanopartikel (DE-588)4333369-2 gnd |
| topic_facet | Nanotecnologia Nanoparticles Nanostructured materials Nanotechnologie Nanostrukturiertes Material Nanopartikel Aufsatzsammlung |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016392456&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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