Nanomaterials 1
Nanoscopic Materials
Size is another variable to change physical and chemical properties
Each physical property or fenomenon has a characteristic length
When particle size is comparable to the characteristic length,
property start to depend on the size
Nanomaterials 2
Nanoscopic Materials
Nanomaterials 3
Nanoparticles 1 – 100 nm Traditional materials > 1 m
Nanoscopic Materials
1 nm = 109 m
1 nm = 10 Å
Nanomaterials 4
Size 1 – 100 nm
Nanoscopic Materials
EU definition (2011):
A natural, incidental or manufactured material containing
particles, in an unbound state or as an aggregate
or as an agglomerate and where, for 50% or more of the
particles in the number size distribution, one or more external
dimensions is in the size range 1 nm – 100 nm.
http://ec.europa.eu/environment/chemicals/nanotech/faq/definiti
on_en.htm
Nanomaterials 5
Nanoscale regime
Size 1 – 100 nm (traditional materials > 1 m)
Physical and chemical properties depend on the size !!
Natural examples:
 Human teeth, 1-2 nm fibrils of hydroxyapatite Ca5(PO4)3(OH) +
collagen
 Asbestos, opals, calcedon
 Primitive meteorites, 5 nm C or SiC, early age of the Solar system
Nanoscale objects have been around us, but only now we can observe
them, manipulate and synthesize them.
Nanoscopic Materials
Nanomaterials 6
“Prey”, the latest novel by Michael Crichton, author of “Jurassic Park”.
The horrible beasties threatening humanity in this new thriller are not giant
dinosaurs, but swarms of minute “nanobots” that can invade and take control
of human bodies.
Last summer, a report issued by a Canadian environmental body called the
action group on erosion, technology and concentration took a swipe at
nanotechnology. It urged a ban on the manufacture of new nanomaterials
until their environmental impact had been assessed. The group is better
known for successfully campaigning against biotechnology, and especially
against genetically modified crops.
The research, led by a group at the National Aeronautics and Space
Administration's Johnson Space Centre in Houston, has found in preliminary
studies that inhaling vast amounts of nanotubes is dangerous. Since they are,
in essence, a form of soot, this is not surprising. But as most applications
embed nanotubes in other materials, they pose little risk in reality.
Nanostructural Materials
Nanomaterials 7
Room at the Bottom
Nanomaterials 8
Nanoscale Writing
Nanomaterials 9
STM
Scanning Tunelling Microscopy
Binning and Rohrer
Nobel 1986
Nanoscale Writing
Nanomaterials 10
STM positioned Xe atoms on Ni crystal, 5 nm letters
Nanomaterials 11
Nanoscopic Materials
Negligible light scattering - New optics
Quantum size effects - Information technology, Storage
media
High surface area - Catalysts, Adsorbents
Large interfacial area - New composites
Surface modifications - Targeted drug delivery
Nanomaterials 12
Nanoscopic Size
The largest known bacterium Thiomargarita
namibiensis - 100-750 microns
Nanomaterials 13
The Nano-Family
At least one dimension is between 1 - 100 nm
0-D structures (3-D confinement):
• Quantum dots
• Nanoparticles
AFM 1 μm x 1 μm
InAs on GaAs/InP Au nanoparticles
CdTe nanoparticles
Nanomaterials 14
The Nano-Family
1-D structures (2-D confinement):
• Nanowires
• Nanorods
• Nanotubes
• Nanofibers
Nanomaterials 15
Electrospinning
Nanomaterials 16
The Nano-Family
2-D structures (1-D confinement):
• Thin films
• Planar quantum wells
• Superlattices
• Graphene
• SAM
Nanomaterials 17
Coherence Length, d
XRD patterns of iron oxide nanocrystals
of 4, 6, 8, 9, 10, 11, 12, 13, and 15 nm


cos
k
d 
Scherrer equation k = 0.89,  = wavelength,
β = full width at half-maximum of a
standard (Si)
Nanomaterials 18
Decreasing grain size = Increasing volume fraction of grain
boundaries (50% for 3 nm particles)
Surface Effects
Ru particle
diameter 2.9 nm
Nanomaterials 19
Surface Effects
Dispersion F = the fraction of
atoms at the surface
F is proportional to surface area
divided by volume
N = total number of atoms
V ~ r3 ~ N
n = number of atoms at the cube edge
33
2
11
Nrr
r
F 
F
Nanomaterials 20
Si
.
Surface Effects
Properties of grain boundaries
Lower coordination number of atoms
Reduced atomic density (by 10 – 30 %)
Broad spectrum of interatomic distances
Experimental evidence
HREM
EXAFS, reduced number of nearest and next-nearest neighbors
 Raman spectroscopy
 Mössbauer spectroscopy, quadrupole splitting distribution broadened
Diffusivity enhanced by up to 20 orders of magnitude !!
Solute solubility in the boundary region
Ag (fcc) and Fe (bcc) immiscible in (s) or (l), but do form solid solution as
nanocrystalline alloy
EPR, nano-Si gives a sharp signal
Nanomaterials 21
Surface Effects
Atoms at surfaces have fewer neighbours than atoms in the bulk
Lower coordination and unsatisfied bonds
surface atoms are less stabilized than bulk atoms
The smaller a particle the larger the fraction of atoms at
the surface, and the higher the average binding energy per
atom
The melting and other phase transition temperatures scale with surfaceto-volume
ratio and with the inverse size
Example: the melting point depression in nanocrystals
2.5 nm Au particles 930 K bulk Au 1336 K
Nanomaterials 22
Surface Effects
A = Atoms at surfaces (one layer) – fewer neighbours, lower coordination,
unsatisfied (dangling) bonds
B = Atoms close to surface (several layers) – deformation of coordination sphere,
distorted bond distances and angles
C = Bulk atoms – not present in particles below 2 nm
Nanomaterials 23
Graphite shells
Nanomaterials 24
Surface Effects
Calculated mean coordination number <NN> as a function of
inverse radius, represented by N1/3 for Mg clusters
(triangles = icosahedra, squares = decahedra, diamonds = hcp
coordination number
Nanomaterials 25
Surface Effects
Atom binding (vaporization) energies lower in nanoparticles,
fewer neighbors to keep atoms from escaping
Plasticity of nanocrystalline ceramics
Surface Effects
Nanomaterials 26
Alloys:
Core-shell
Janus
Random mixture
Au-Pt 586 atoms
Nanomaterials 27
Melting Point Depression

















3
2
2
)(
L
s
Ls
s
bulk
m
bulk
m
m
bulk
m
rH
T
rTTT




Sn - 0,5wt%Cu - 4wt%Ag Nano alloy particles
Nanomaterials 28
Gibbs–Thomson Equation
rH
V
T
TrT
m
sl
l
mol
bulk
m
bulk
mm


 2)(
Tm(r) = mp of the cluster with radius r
Tm
bulk = mp of the bulk
Vmol
l = the molar volume of the liquid
 sl = the interfacial tension between the s and l surface
Hm
bulk = the bulk latent heat of melting
DSC
In nanoparticles confined in pores
bulk
Nanomaterials 29
Phase Transitions
Phase transitions = collective phenomena
With a lower number of atoms in a cluster a phase
transition is less well defined and broadened
Small clusters behave more like molecules than as
bulk matter
bulk
bulk
First-Order Phase Transitions
Nanomaterials 30
3 main consequences of a size decrease on caloric curve:
* The transition is shifted, usually to a lower temperature (surface atoms are less
coordinated and less bound than interior atoms)
* The transition temp. is no longer sharp but becomes smooth and takes place over
a finite range (fluctuations in TD quantities)
* The latent heat is lower than in the bulk limit
Nanomaterials 31
Surface Effects
Reduction in particle size
•metal particles usually exhibit a lattice contraction
•oxide particles exhibit a lattice expansion
YIG = Y3Fe5O12
Nanomaterials 32
Surface Effects
Correlation between the unitcell
volume (cubic) and the
XRD particle size in -Fe2O3
nanoparticles
The smaller the particle size the
larger the unit cell volume.
Nanomaterials 33
Surface Effects
The inter-ionic bonding in nanoparticles has a directional character
ions in the outermost layer of unit cells possess unpaired electronic
orbitals
Associated electric dipole moments, aligned roughly parallel to each
other point outwards from the surface
The repulsive dipolar interactions increase in smaller particles
reduced by allowing unit cell volume to increase
Nanomaterials 34
 Finite-size effects
MO to Band transition
Quantum Confinement Effects
Physical and chemical properties depend on the size !!
Nanomaterials 35
Metal-to-Insulator Transition
Nanomaterials 36
Nanomaterials 37
Band gap increases with decreasing size
Metal-to-Insulator Transition
Metallic behavior
Single atom cannot behave
as a metal
nonmetal to metal transition
100-1000 atoms
Magnetic behavior
Single domain particles
large coercive field
Nanomaterials 38
Metal-to-Insulator Transition
Variation of the shift, E, in the core-level binding energy
(relative to the bulk metal value) of Pd with the nanoparticle diameter
The increase in the core-level binding
energy in small particles
poor screening of the core charge
the size-induced metal-nonmetal
transition in nanocrystals
Nanomaterials 39
Electrical Conductivity
Particle size
Bulk value
Relativeconductivity
Nanomaterials 40
Photoelectron spectra of Hg clusters of nuclearity n
The 6p peak moves gradually towards the Fermi level
the band gap shrinks with increase in cluster size
6s
HOMO
6p
LUMO
Nanomaterials 41
a) Absorption spectra of CdSe
nanocrystals (at 10 K) of various
diameters
b) Wavelength of the absorption
threshold and band gap as a function of
the particle diameter for various
semiconductors. The energy gap in the
bulk state in parenthesis
Nanomaterials 42
Quantum Confinement Effects
Fluorescence of CdSe–CdS core–shell nanoparticles with a
diameter of 1.7 nm (blue) up to 6 nm (red)
Smaller particles have a wider band gap
Nanomaterials 43
Bohr Radii
Quantum confinement - particles must be smaller than the
Bohr radius of the electron-hole pair
Nanomaterials 44
 Optical properties
nc-TiO2 is transparent
Blue shift in optical spectra of nanoparticles
Quantum Confinement Effects
Nanomaterials 45
a) Variation of the nonmetallic band gap
with nanocrystal size
b) in CdS nanocrystals
Nanomaterials 46
NANO -particles, crystals, powders
-films, patterned films
-wires, rods, tubes
-dots
Nanostructured materials = nonequilibrium character
good sinterability
high catalytic activity
difficult handling
adsorption of gases and impurities
poor compressibility
PREPARATION METHODS
Top-down: from bulk to nanoparticles
Bottom-up: from atoms to nanoparticles
Nanoscopic Materials
Nanomaterials 47
Preparation Methods
Top-down: from bulk to nanoparticles
Bottom-up: from atoms to nanoparticles
Nanomaterials 48
Bottom-up Synthesis: Atom Up
Nanomaterials 49
NANOSTRUCTURAL MATERIALS
 Atom Aggregation Method
GEM – gas evaporation method
 evaporation by heating – resistive, laser, plasma, electron beam,
arc discharge
 the vapor nucleates homogeneously owing to collisions with the
cold gas atoms
 condensation
in an inert gas (He, Ar, 1kPa) on a cold finger, walls - metals,
intermetallics, alloys, SiC, C60
in a reactive gas O2 TiO2, MgO, Al2O3, Cu2O
N2, NH3 nitrides
in an organic solvent matrix
Bottom-up Synthesis
Nanomaterials 50
NANOSTRUCTURAL MATERIALS
SMAD – the solvated metal atom dispersion
1 – 2 g of a metal, 100 g of solvent, cooled with liquid N2
more polar solvent (more strongly ligating) gives smaller particles
Ni powder: THF < toluene < pentane = hexane
Carbide formation
Ni(g) + pentane NixCyHz Ni3C
77 to 300 K 180 C, octane
Bottom-up Synthesis
Nanomaterials 51
NANOSTRUCTURAL MATERIALS
 Thermal or Sonocative Decomposition of Precursors
Fe(CO)5 nc-Fe + 5 CO sono
[Co(en)3]WO4 nc-WC – 23% Co
PhSi(OEt)3 + Si(OEt)4 + H2O gel -SiC
(CH3SiHNH)n (l) Si3N4 + SiC laser
M(BH4)4 (g) borides MB2+x (M = Ti, Zr, Hf)
Si(OEt)4 + Ag+
or Cu2+
+ H2O SiO2/Ag+
/Cu2+
SiO2/Ag/Cu
Ar, 1500 C
300-400C
H2, 550 C
Bottom-up Synthesis
Nanomaterials 52
NANOSTRUCTURAL MATERIALS
 Reduction of Metal Ions
Borohydride Reduction - Manhattan Project
Aqueous, under Ar
2 Co2+
+ 4 BH4
+
9 H2O Co2B + 12.5 H2 + 3 B(OH)3
Under air
4 Co2B + 3 O2 8 Co + 2 B2O3
Nonaqueous
Co2+
+ BH4
+
diglyme Co + H2 + B2H6
TiCl4 + 2 NaBH4 TiB2 + 2 NaCl + 2 HCl + H2
MXn + n NR4[BEt3H] M + NR4X + n BEt3 + n/2 H2
M = group 6 to 11; n = 2,3; X = Cl, Br
mixed-metal particles
Bottom-up Synthesis
Nanomaterials 53
NANOSTRUCTURAL MATERIALS
Au colloidal particles
HAuCl4 + NaBH4 in toluene/H2O system,
TOABr as a phase transfer agent, Au
particles in the toluene layer, their surface
covered with Br, addition of RSH gives
stable Au colloid
Au
fcc
S
S
S
S
S
S
S
S
S
S
S S
S
Bottom-up Synthesis
Nanomaterials 54
Bottom-up Synthesis
SH
Nanomaterials 55
Two-dimensional array of
thiol-derivatised Au particles
(mean diam 4.2 nm)
Nanomaterials 56
TEM micrograph of hexagonal arrays
of thiolized Pd nanocrystals:
a) 2.5 nm, octane thiol
b) 3.2 nm, octane thiol
Nanomaterials 57
The d-l phase diagram for Pd nanocrystals thiolized with different alkane thiols.
The mean diameter, d, obtained by TEM.
The length of the thiol, l, estimated by assuming an all-trans conformation of the alkane chain.
The thiol is indicated by the number of carbon atoms, Cn.
The bright area in the middle encompasses systems which form close-paced organizations of
nanocrystals. The surrounding darker area includes disordered or low-order arrangements of
nanocrystals. The area enclosed by the dashed line is derived from calculations from the soft
sphere model
Nanomaterials 58
NANOSTRUCTURAL MATERIALS
K +
K+
Mg
Mg
in dry anaerobic diglyme, THF, ethers, xylene
NiCl2 + 2 K  Ni + 2 KCl
AlCl3 + 3 K  Al + 3 KCl
Reduction by Glycols or Hydrazine
“Organically solvated metals”
Alkali Metal Reduction
Nanomaterials 59
Alkalide Reduction
13 K+(15-crown-5)2Na + 6 FeCl3 + 2CBr4
THF
30 °C
2 Fe3C (nano) + 13 K(15-crown-5)2Cl0.43Br0.57 + 13 NaCl
Anealed at 950 °C / 4 h
Fe3C: 2 – 15 nm
Nanomaterials 60
NANOSTRUCTURAL MATERIALS
 Reactions in Porous Solids – Zeolites, Mesoporous materials
Ion exchange in solution, reaction with a gaseous reagent inside the
cavities
M2+
+ H2E ME M = Cd, Pb; E = S, Se
Ship-in-the-Bottle Synthesis
Ru3+
+ Na-Y Ru(III)-Y
Ru(III)-Y + 3 bpy Ru(bpy)3
2+
reduction of Ru(III)
Conducting carbon wires
Acrylonitrile introduced into MCM-41 (3 nm diam. channels)
Radical polymerization
Pyrolysis gives carbon filaments
Bottom-up Synthesis
Nanomaterials 61
NANOSTRUCTURAL MATERIALS
 Gel or Polymer Matrices
 Sol-Gel Method
Aerogels, supercritical drying
 Aerosol Spray Pyrolysis
Aqueous solution, nebulization, droplet flow, solvent evaporation,
chemical reaction, particle consolidation, up to 800 C
3Gd(NO3)3 + 5 Fe(NO3)3 Ga3Fe5O12 + 6 O2 + 24 NO2
MnCl2 + 2 FeCl3 + 4 H2O MnFe2O4 + 8 HCl
Mn(NO3)2 + Fe(NO3)3 no go, why?
Bottom-up Synthesis
2 MCln (g) + n H2  M0 + 2n HCl
850-900 C
3-11 nm
Nanomaterials 62
NANOSTRUCTURAL MATERIALS
 Inverse Micelles
H2O +
octane
H2O
H2O
Cd2+ Se2-
CdSe
CdSe
PhSeSiMe3
Bottom-up Synthesis
Nanomaterials 63
Bottom-up Synthesis
Nanomaterials 64
Bottom-up Synthesis
180 °C in octylamine
200 °C in dodecylamine
Phase Control
[NnBu4]2[Fe4S4(SPh)4]
pyrrhotite Fe7S8
greigite Fe3S4
thiospinel, the sulfide analogue of
magnetite
Nanomaterials 65
Polymeric Nanoparticles from Rapid Expansion of
Supercritical Fluid
Solution
Nanomaterials 66
Polymeric Nanoparticles from Rapid Expansion of
Supercritical Fluid
Solution
Nanomaterials 67
Nanomaterials 68
Spinning Disc Processing (SDP)
A rapidly rotating disc (300-3000 rpm)
Ethanolic solutions of Zn(NO3)2 and NaOH, polyvinylpyrrolidone (PVP) as a
capping agent
Very thin films of fluid (1 to 200 m) on a surface
Synthetic parameters = temperature, flow rate, disc speed, surface texture
influence on the reaction kinetics and particle size
Intense mixing, accelerates nucleation and growth,
affords monodispersed ZnO nanoparticles with controlled particle size down to
a size of 1.3 nm and polydispersities of 10%
Nanomaterials 69
NANOSTRUCTURAL MATERIALS
Properties on Nanostructured Materials
 Metallic behavior
Single atom cannot behave as a metal
nonmetal to metal transition : 100-1000 atoms
 Magnetic behavior
Single domain particles, large coercive field
 Depression of melting points in nanocrystals
bulk Au mp 1064 C 10 nm Au 550 C
Nanomaterials 70
LaMer mechanism
Supersaturated solution
Burst of nucleation
Slow growth of particles without
additional nucleation
Separation of nucleation and growth
Nanomaterials 71
Watzky-Finke mechanism
Slow continuous nucleation
Fast autocatalytic surface growth
Nanomaterials 72
Seed-mediated mechanism
Au nanoclusters as seeds
Bi, Sn, In, Au, Fe, Fe3O4
Nanomaterials 73
Other mechanisms
Digestive rippening
Surfactant exchange
Nanomaterials 74
Thermal Decomposition of Precursors
Fe(CO)5 oleic acid
trioctylamine
350 o
C, 1 h
350 o
C, 1 h
Fe
Me3NO
Fe2O3
6 nm
Separation of nucleation and growth
Fe(CO)5 thermal decomposition at 100 oC contributes to nucleation
Fe(oleate) thermal decomposition at 350 oC contributes to growth
OH
O
Surface Modification
Nanomaterials 75
A nanoparticle of 5nm core diameter
with different hydrophobic ligand
molecules both drawn to scale.
The particle is idealized as a smooth
sphere.
trioctylphosphine oxide (TOPO)
triphenylphosphine (TPP)
dodecanethiol (DDT)
tetraoctylammonium bromide (TOAB)
oleic acid (OA)
Nanomaterials 76
Top-down Synthesis: Bulk Down
 Introduction of Crystal Defects (Dislocations, Grain
Boundaries)
High-Energy Ball Milling
final size only down to 100 nm, contamination
 Extrusion, Shear, Wear
High-Energy Irradiation
 Detonative Treatment
 Crystallization from Unstable States of Condensed Matter
 Crystallization from Glasses
Precipitation from Supersaturated Solid or Liquid Solutions
Nanomaterials 77
Top-down Synthesis: Bulk Down
Lithographic Techniques
electron beam and focused ion beam (FIB) lithography
Nanomaterials 78
Top-down Synthesis: Bulk Down
Lithographic Techniques
electron beam and focused ion beam (FIB) lithography
Nanomaterials 79
Nanocatalysis
Morphologies of bimetallic nanoparticles
Nanomaterials 80
Nanocatalysis
Polymers used as metal NP supports for catalysis
Nanomaterials 81
Nanocatalysis
Catalysis by nanoparticles encapsulated in PAMAM or PPI dendrimers
Nanomaterials 82
Nanocatalysis
Asymmetric heterogeneous catalysis on nanoparticles
Nanomaterials 83
Hollow Nanoparticles
formation of hollow spheres
Nanomaterials 84
Applications
Destruction of dangerous organic compounds
(organophosphates - VX, chlorinated - PCB)
Nanomaterials 85
CNT growth
Nanomaterials 86
Nanoengine
Nanoengine runs on catalytic reactions:
Pt part splits H2O2 to O2 and protons H+.
Excess electrons move to Ag/Au, reduce H2O2 and protons to water.
Release of O2 causes streaming that propels the engine through the liquid
150 micrometers per second
Joseph Wang UC San Diego and Arizona State
Nanomaterials 87
Growth twinning in gold nano-particle
The Moiré-fringe image of a 30 nm decahedral gold nanoparticle shows five-fold rotational symmetry (black fringes) that results from
serial twinning and shows the internal distortion of the atomic structure (indicated by the gradual change of the color fringes) that
accommodates this unique geometry. The Moiré-fringe image was extracted from the original TEM image taken on the sphericalaberration-corrected
Tecnai F20 at the CEMES-CNRS in Toulouse, France. Such particles have tremendous potential as components of
nanoscale plasmonic devices for imaging, cancer therapy, and biosensing among other applications.