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Overview of Nanoparticle MaterialsJohn Texter
College of Technology, Eastern Michigan University, Ypsilanti, MI
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Particle Synthesis, Particle Modification
Particle Characterization
Particle-Based Materials
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Synthesis and ModificationGas Phase (Pratsinis)
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Synthesis and ModificationGas Phase (Pratsinis)
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Synthesis and ModificationLiquid Feed Flame-Spray Pyrolysis (Laine)
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Synthesis and ModificationSegmented Flow Tube Reactor (Hoffman)
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Synthesis and ModificationHydrothermal (Matijevic)
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Synthesis and ModificationBinary Metal Oxides - Nonaqueous Sol-Gel (Niederberger)
General Synthesis General Synthesis ProtocolProtocol::
1) Metal Alkoxide + Benzyl Alcohol(C6H5CH2OH)
Metal Alkoxides:
VO(OiPr)3, Nb(OEt)5, Hf(OEt)4, Ta(OEt)5, Sn(OtBu)4, In(OiPr)3
2) Heat Treatment in Autoclave at 200°C-250°C Ta2O5
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Synthesis and ModificationMonodisperse Particles from Aggregation of Nanoparticles (Matijevic)
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Synthesis and ModificationMonodisperse Emulsions (Pine)
polar fluid+ surfactant
polymer particles
monomerliquid
swell with monomer
polymerize monomers Mw small
swell with oil
Add solvent (oil) for polymer
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Synthesis and ModificationBarium Sulfate Morphogenesis (Coelfen, Qi)
2μm
0.5μm
0.5μm
2μm
PEGPEG--bb--PEIPEI--SOSO33HH
PEGPEG--bb--PMAAPMAA--POPO33HH22
PEGPEG--bb--PMAAPMAA--AspAsp
2μm
PEGPEG--bb--PEIPEI--COOHCOOH
NoNo additiveadditive
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Synthesis and ModificationSIP (Advincula)
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Synthesis and ModificationBlock Copolymers as Nanoreactors (Advincula)
Cationicpolyelectrolytes
Amphiphilicblock copolymers
(PS-b-P2VP)
Dendrimers(PAMAM)
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Synthesis and ModificationMicrogels by Dispersion Polymerization (Lyon)
Oligoradical Precursor ParticleGrowing Particle Microgel
Precipitation Polymerization
NHO NH
NH
O
OX
O+ +SDS
APS
70 oC
>4 hrs.
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Synthesis and ModificationFunctionalization (Hoffman)
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Synthesis and ModificationLigand Coated Metal Nanoparticles (Stellacci)
Metal Salt (AuHCl4) + HSReducing Agent (NaBH4)+
HS
Ligand exchange reaction*
Direct mixed ligands reaction**
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Synthesis and ModificationQuantum Dots in Frogs (Norris)
Me2Cd Se CdSe NCs
320 °C
• diameters between 2nm to 12nm• size distributions
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Synthesis and Modificationin Reverse Micelles (Pinna)
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Synthesis and ModificationMicroemulsion Polymerization (Kaler)
P•
MM M M
PM•
MM
M
M M
MM
M
M
MM
M
M
I•
IM•M•
310~Particles#Micelle#
Initiation by IM•
Propagation
Initiationby M•
ChainTransfer
M
M
M
M
M
5 nm
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Synthesis and ModificationTemplating in Matrices (Braun)
z 5 mmzz
x
y
zzzzzz
xx
yy
xx
yy
xx
yy
xx
yy
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Synthesis and ModificationReplacement of Ag by Au (Xia)
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Synthesis and ModificationStretching Polymer Beads (Xia)
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Synthesis and ModificationDimeric Colloids (Xia)
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Synthesis and ModificationGeometrical Clusters (Pine)
silica spheres
11
silica-coatedPMMA spheres
11
4 5 6 7
8 9 10 11
118 9 10
3 4 5 6 7
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Synthesis and ModificationColloidal Molecules (Pine)
2 3 4
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Synthesis and ModificationEncapsulation (Velev)
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CharacterizationConfocal Microscopy (Wiltzius)
photomultiplier tube
objective lens, e.g. 100x
laser
illuminating aperture
dichroic beamsplitter
confocal aperture
focal planesample
in focusout of focus
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CharacterizationSurface Charge in Heterocoagulation (Matijevic)
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CharacterizationAnalytical Ultracentrifugation (Coelfen)
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CharacterizationHRTEM (Pinna)
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CharacterizationTEM Image Analysis (Coelfen)
0.80.8 1.21.2 1.61.6 2.02.0 2.42.4 2.82.8 3.23.2 3.63.600
55
1010
1515
2020350350 countscounts
particle diameterparticle diameter [nm][nm]
Num
ber f
requ
ency
%
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CharacterizationParticle Interaction Potentials (Yodh)
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CharacterizationSANS (Kaler)
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CharacterizationRheology (Weitz)
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Particle-Based Materials
Particle Assembly
Thermodynamics
Functional Materials
Devices
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Particle AssemblyThermodynamics (Wiltzius)
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Particle AssemblyEntropy Drives Growth (Weitz)
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Particle AssemblyEntropy and Other Forces (Yodh)
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Particle AssemblyDielectrophoreticMicrowire Assembly(Velev)
AC Voltage
Grounded
FDEP
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Particle Assembly2D Epitaxy (Yodh)
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Particle AssemblyTemplate Assisted Assembly (Niederberger)
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Particle AssemblyTemplated Clusters (Xia)
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Particle Assembly2D Dielectrophoretic Assembly (Velev)
Fourier transform Diffraction pattern
5 s
15 s
Optical micrograph
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Particle AssemblyDomain sizes too small (Wiltzius)
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Particle AssemblyConvective Crystallization (Xia)
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Particle AssemblyConvective Assembly(Velev)
- Ambient light
- Low angleLight transmission
cm2 coatings from μL drops in minutes1.1 μm latex crystal viewed with:
1cm
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Particle AssemblyCCAs to close-packed photonic xtals (Wiltzius) no salt
salt
electrostaticsdominate
screenedelectrostatics
VdW’s attraction“guide” adhesion
add salt
Charge Stabilized
u(r)
rvan der Waals
attraction
electrostaticrepulsion
Screened
u(r)
r
screening
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Particle AssemblyModifying interactions and annealing in microgel photonic materials (Lyon)
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Particle AssemblyStrategies for Assembling Anisotropic Structures (Niederberger)
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Particle AssemblySelf-Assembly of Nanoparticles (Niederberger)
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Particle AssemblyChains with Given Handedness (Xia)
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Particle AssemblyColloidal Crystalline Arrays (Asher)
~ 1013 spheres/cm3
spacing dependent only upon particle number density and crystalline structure
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Dialysis /Ion Exchange Resin
Self-assembly
Crystalline Colloidal Array
FCC--
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- -
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Particle AssemblyMechanism of Convective Crystallization(Norris)
100X
microscopeobjective
immersionoil
CC
D
video camera
800nm spheres
real time video
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Particle AssemblyBiomineralization (Coelfen)
SEM ofSEM of broken mussel broken mussel shellshell
SEM ofSEM of broken mussel broken mussel shell after proteinshell after protein
removalremoval
SEM ofSEM of broken mussel broken mussel shell after shell after CaCOCaCO33
removalremovalTEM TEM thin cutthin cut ofofdeveloping developing mussel shellmussel shell
SEM ofSEM ofdeveloping developing mussel shellmussel shell
SEM SEM mature mussel mature mussel shellshell
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Particle AssemblyMagnetically Driven Assembly (Asher)
350 400 450 500 550 600 650 7000
2
4
6
NaCl Concentration (From left to right)4.0mM, 2.0mM, 1.0mM, 0.67mM, 0.33 mM,0.16 mM, 0mM
Rel
ativ
e in
tens
ity
wavelength (nm)
0 1 2 3 4
160
180
200
220
240FC
C (1
11) p
lane
spc
aing
/ nm
NaCl concentration / mM
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Particle AssemblyBalancing Interfacial Interactions (Coelfen)
Nucleationclusters
Primary nanoparticles> 3 nm
Crystal growth
Amplification Mesoscale assembly
Single crystal Iso-orientedcrystal
TemporaryStabilization Mesoscale
assembly
Mesocrystal
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Particle AssemblyBalancing Interfacial Interactions (Hoffman)
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Particle AssemblyCopper Oxalate Assembly (Hoffman)
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Functional MaterialsFlame Pyrolysis (Laine)
• Pure nano α-Al2O3• Abrasives
–Chemical mechanical polishing• Transparent ceramics
–Sodium vapor lamps–Ti:Sapphire lasers among other things.
• Coatings• High strength monoliths
–Ceramic prosthetics for example• Catalyst supports that do not sinter• Catalysts
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Functional MaterialsMicroporous and Mesoporous Materials (Stein)
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Functional MaterialsInorganic Pigments (Stein)
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Functional MaterialsPhotonic Crystals (Norris)
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Functional MaterialsHierarchically Ordered Structures (Pine)
PDMS Master(10 µm
structures)Place on substrate
Place a drop of suspension of
polystyrene spheres at one end (1 µm
structures)
Fill channels by capillary flow; evaporate solvent.
Place sol droplet; fillSpace between latex particles by capillary flow.
Allow to gel. RemovePDMS master. Calcine.
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Functional MaterialsTwo Photon Fab (Braun)
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Functional MaterialsOptical Switch (Asher)
S NN S
500 600 700
1
2
3
4
5
6
Rel
ativ
e In
tens
ity (a
.u.)
-20 Oe -9 Oe +9 Oe +20 Oe
Rel
ativ
e In
tens
ity (a
.u.)
Wavelength /nm-120 -90 -60 -30 0 30 60 90 120
1
2
3
4
5
6
686 nm 549 nm
H / Oe
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Functional MaterialsMetal Cation Sensors (Asher)
500 550 600 650 700 750 800
bu ffe red sa line
5 m M
2 m M0.5 m M
54 μM0.54 μM
1 μM
11 nM
Diff
ract
ion
inte
nsity
/ a.
u.
λ / nm
No Cu2+11 nM0.54 μM1 μM
54 μM 0.5 mM 2 mM 5 mM
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Functional MaterialsGlucose Sensing (Braun)
HydrogelFlow cell
Inflow from syringe pump
10x ObjectiveBeamsplitter
Optical fiberPinhole
Light source
PhotodiodeArray
Detector
Outflow
RBOH
OHRB
OHOHOH
O
RBOH
OO
OH
OH
OH
Glucose-PBA complex
PBA (phenylboronic acid)
1 mM glucose
0 mM glucose[Glucose]0 mM 100 mM
SEM of templated hydrogel
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Functional MaterialsGyricon Display (Morrison)
Charged,bichromalballs.
Suspendedin an oil.
Encased ina plasticsheet.
Addressedwith electrodes. That Xerox
built.
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Functional MaterialsElectrophoretic Display (Morrison)
Sony’s LIBRie EBR-1000EP from E Ink and Phillips Electronics
Negativelychargedpigmentparticles.
Positivelychargedpigmentparticles.
Suspendedin a clear oil.
Addressedwith electrodes.
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Functional MaterialsElectrochromic Devices (Kotov)
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Functional MaterialsDonor-Acceptor Tagging (Kotov)
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Functional MaterialsInsulin Incorporation and Release (Lyon)
Linear increase in insulin content with
particle layer number.
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Functional MaterialsGlucose Sensing (Asher)
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Functional MaterialsLab on a Chip (Velev)
gold nanoparticles →
sulfate latex →
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Functional MaterialsQuantum Dots in Frogs (Norris)
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Acknowledgments
• Liehui Ge, Swapnil Bondre, Swapna Devireddy
• Lecturers• Students for their participation and
stimulation• Petroleum Research Fund ($$$$)
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Overview of Nanoparticle MaterialsJohn Texter
College of Technology, Eastern Michigan University, Ypsilanti, MI
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