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Physics and Chemistry of Hybrid Organic-Inorganic Materials Lecture 4: The physics of phase separation and solutions
Physics and Chemistry of Hybrid Organic-Inorganic
MaterialsLecture 4: The physics of phase separation and
solutions
Professor Douglas A. LoyVisiting from the University of Arizona,
United States
Key points for phase separation and solutions
Phase separation is thermodynamicPhase separation is a part of most
hybrids formationSol-gel systems form supersaturated solutions that
phase separate solid particles (nucleation control).Sol-gel
polymerization of hybrid monomers leads can lead to single solid
phases, but there is often a liquid or gas phase created by
particle percolation and gelation.Hybrid based on organic polymers
undergo enthalpically driven phase separationsThere are nucleation
and thermodynamic (spinoidal) controlled phase
separations.Particles form by nucleation phase separationSurfactant
templating is the formation of a material in one phase of a phase
separated surfactant-solvent system
Phase separation in Hybrid systems
Phase separation occurs frequently in the formation and processing
of hybrid organic-inorganic materialsYou must be able to recognize
how many phases are present in order to characterize and understand
a hybrid material.
It is not always as easy as with oil and water to tell how many
phases are present
Hybrid Organic-Inorganic Thermodynamics of Mixing/Phase
separation
phase separation and mixing are opposite thermodynamic processesWe
will describe the thermodynamics of these processes with Helmhotz
free energy, F
For either: F < 0 means phase change is favorableF > 0
means the existing state is more stable and no change.
F = U TS
Thermodynamics of single component phase changes
Thermodynamics of single component phase changes
Thermodynamics of mixing: Two phases going to become one
F
Inorganic
organic
2 phases
One phase: a solution
Dissolution
F (mixing) = U TS < 0
In this case, the change Helmhotz free energy:
Thermodynamically favorable mixing of two phases into one
S is generally positive for mixing & gets larger with
temperatureU is often positive (unfavorable) with mixing
polymers.
Rare, but this could occur with an inorganic monomer dissolving in
a polymer
Thermodynamics of phase separation: One phase unable to separate
into two
F
Inorganic
organic
2 phases
One phase: a solution
F(phase separation) = U TS > 0
In this case, the change Helmhotz free energy:
Thermodynamically unfavorable phase separation: uphill
The kT at this time is insufficient to drive phase
separation.
Hybrids with organic and inorganic components bonded together at
the monomer level are unable to phase separate
Thermodynamics of mixing: Two phases not changing
Inorganic
organic
2 phases
Insoluble
F(mixing) = U TS > 0
Inorganic
organic
still two phases
Either temperature is not high enough to dissolve the
particlesand/or the U (internal energy; like enthalpy) is too
positive for the entropy to overcome
This is what happens with mixing inorganic particles and organic
polymer.
An example of a hybrid composed of inorganic (silica) particles
mixed in with a fluorinated polymer electrolyte (Nafion)
5 weight percent ex situ silica in Nafion
Two solidimmiscible phases
Must be physically mixed
Thermodynamics of mixing: one phase separating into two
F
Inorganic
organic
2 phases
One phase: a solution
F (Phase separation) = U TS < 0
Thermodynamically favorable phase separation of one phase into two
phases: This is how particles form in sol-gel and what can happen
when a monomer dissolved in another polymer polymerizes.
Phase separation of particles from an inorganic monomer
dissolved in a viscous polymer solution
In situ Silica particles
The silica monomer forms oligomers and polymers that eventually
nucleate out as spherical particles
Phase diagram of a hybrid organic inorganic material
Two phases at lower temperaturesOne phase at higher
temperaturesMaximum insolubility is when there are nearly equal
quantities in the mixture.
Phase diagram of a hybrid organic inorganic material: Effect
Molecular weight on phase separation
With increasing molecular weight of one or both of the solutes, the
phase boundary (binodal line) increases in temperatureAs Mw
increases entropy change becomes less positive.Hybrids often
experience phase separation
Bold line highest molecular weightDashed line lowest molecular
weight
More information from phase diagrams: Plots of F at different
temperatures
(a)
(b)
(c)
(d)
(a)
(b)
(d)
(c)
unstable
stable
Overlaying the plots of F on the original phase diagram reveals
a metastable region
(a)
(b)
(c)
(d)
unstable
stable
metastable
metastable
Inorganic rich phasecomposition
organic rich phasecomposition
spinodal lines
spinodal line
spinodal lines
binodal line
red = spinodal lineblue - binodal
binodal line
Two phase separation processes:
Spinodal decomposition: spontaneous. Fingerprint like patterns.
Between spinodal lines Nucleation-not spontaneous, requires
nucleationspherical particles-surface energy importantnucleation
kinetics important
spinodal
nucleation
nucleation
red = spinodal lineblue - binodal
Spinodal phase separated materials
Freeze fracture TEM
spinodal
nucleation
nucleation
red = spinodal lineblue - binodal
Block copolymers
Nucleation phase separated materials
spinodal
nucleation
nucleation
red = spinodal lineblue - binodal
Freeze fracture TEMs
Spinodal decomposition is mostly about bulk FNucleation also has to
account for the instability of the particles due to their small
size.
Thermodynamics of silica particles forming in sol-gel by
nucleation
Common monomer for silica is Si(OEt)4 Reactions with water Alcohol
is solvent because monomer & water are immiscible In solution,
the monomer hydrolyzes to Si(OH)4 & then polymerizesVolume
percent silica is in nucleation zone. Phase separates as particles
only when 1-2 nm in diameter.
Why do the particles grow this big before separating from the solution?
Surface tension & the importance of interfaces
Molecules on surface have fewer neighbors and so exert greater
force on adjacent molecules = surface tension (in dynes cm-1 or N
m-1 Jm-2)
Surface tension = surface energy (N m-1 = Jm-2)
Nature tries to minimize the surface area of interfaces (spheres
and the bigger the better)
It costs energy to phase separate and make an interface
surface area versus diameter for particles
Small particles have higher surface area per gram; higher
energy
Nucleation of a Second Phase in the Metastable Region
Growth of the second phase occurs only when a stable nucleus with
radius r has been formed.
is the interfacial energy between the two phases.
Small: usually a few nanometers
Nucleation free energy plot: critical nuclei size
Surface energy/size driving force for particle Coalescence
Same polymer volume before and after coalescence:
In 1 L of latex (50% solids), with a particle diameter of 200 nm, N
is ~ 1017 particles. Then A = -1.3 x 104 m2
With = 3 x 10-2 J m-2, F = - 390 J.
Hybrid systems: small inorganic particles in an organic
polymer
Particles will aggregate into clusters to reduce surface area and
lower free energy
Other hybrid monomer can undergo a variety of different phase
separations
Must have solid and liquid phase Solid phase (usually particles)
must be continuous through liquid (percolation) Phase separation of
liquid prevents further reaction and gelation
No Gel
No Gel
Gel
With time
The free energy of mixing the oil and water into a (single phase)
solution is very, very, very unfavorable (positive)
Now, lets look at a two phase system that stays 2 phases with
mixing (emulsions)
Two immiscible liquidsminimizing surface area
Two immiscible liquids forced into very high surface area
interface
Meta-stable because of surfactant
Two phases
Two phases
Templating with triblock copolymer is formally a Class 1B
material
Polymer is template. After removal, silica remains
Summation
Phase separation is an important part of how hybrids formMany
hybrids have multiple phasesSome start as mixtures and end as
multiphase mixtures.Hybrid monomers will form single phase bulk
materials, but will form porous materials where air or solvent is a
second phase.The phase separations lead to recognizable structures
and morphology that can tell the researcher how to manipulate the
hybrids productively.
This is just the free energy diagram for a solid melting into a
liquid. Below the melt point the solid phase is more stable and
above the melt point the liquid is more stable (lower in free
energy).
*
Same as before.
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In a two phase system dissolution or making a solution is
thermodyanmically favorable when the change in free energy is
negative. This means that the solution is downhill or has a lower
free energy than the inorganic and organic phases being mixed. This
is not making a mixture. The inorganic phase must actually dissolve
in the organic, not just float around.
*
This phase separation is the reverse of the dissolution shown on
the previous slide. Our solution cannot return to having its
organic and inorganic constituents as separate phases because the
energy cost is too great.
*
This slide represents physically mixing an inorganic phase and an
organic phase to make a mixture that has two phases. The inorganic
cannot dissolve because the thermodynamics are not favorable. You
have to be careful, some cases appear to be insoluble, but really
are soluble with really slow dissolution rates.
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As it says.
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This is the case where a single phase hybrid spontaneously phase
separates into an inorganic phase and an organic phase. This
generally happens when the temperature is reduced or one or both of
the two phases is growing due to polymerization chemistries.
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An example of silica in Nafion membranes made by the process
described on the previous slide.
*
Phase diagrams are an important tool in studying multi-phase
materials. This phase diagram shows the two phases inside the arch
(binodal line) and the solution of the two that forms at higher
temperatures or when one or the other of the phases is in
excess.
*
When molecule weight increases, many molecules are being attached
to each other. This reduces the entropy of the system making the
macromolecule less soluble. This characteristic is widely used to
purify polymers of any residual monomers that will stay in solution
when the polymer is precipitated out with the addition of a
non-solvent for the polymer.
*
The Phase diagram is essentially the top view of a number of free
energy versus composition plots stacked together.
*
This slide shows how we translate from one graph type to the other.
The spinodal lines comes from the observation that the free energy
versus temperature plot looked like a vertebrae. The spinodal lines
are at the inflection point. Between the lines the unstable phase
can decompose productively with essentially no barrier. Between the
spinodal and binodal lines, there is an activation barrier to phase
separation. See latter slides.
*
Each phase separation is a easily recognized characteristic that
provide clues as to what happened with your material. They also
have dramatically different properties.
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When you characterize materials and see this kind of morphology,
you know you have a spinodal phase separation.
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When you characterize materials and see this kind of morphology,
you know you have a nucleated phase separation.
*
*
Any interface costs energy to maintain because the molecules on
each side have better internal energy relationships with their own
kind than with the molecules or atoms in the other phase.
*
Surface area of spheres goes exponential as the diameter gets below
1000 nm. This helps to account for a lot of the weird behavior of
materials made with small particles.
*
Free energy of nucleation. Nucleation is the point at which the
particle goes from being in solution to being a separate
phase.
*
This is a plot of the interfacial energy which is unfavorable and
dependent on the surface area of the particle. The bulk free energy
driving force for phase separation is multiplied by the spherical
geometry correction. Since the surface area increases slower than
volume, the bulk free energy wins out in the end. When the free
energy change for nucleation maxes out and starts to decrease that
is the point that particles start to persist rather than dissolve.
Before that point, any particles will immediately be
dissolved.
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In addition to affecting the critical size of nuclei, the surface
energy will also drive particles to coarsen (grow or coalesce) or
aggregate together. The strong van der Waals attractive forces
possible with small relatively smooth particles making aggregation
hard to reverse. This means that it is hard to make particles
smaller than 100 nm by physical methods because they keep sticking
back together. To do so requires a kinetic stablizer.
*
You can see the particles that have aggregated together in this
Nafion-silica composite membrane in order to minimize their surface
energy.
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Silsesquioxanes, a common hybrid organic-inorganic, will phase
separate out as viscous liquids from the ethanol solution or as
crystals or as particles. Which happens depends on the organic
group on the monomer, monomer concentration, solvent, catalyst and
other variables. When these particles aggregate into a percolating
network, the solvent or air (after drying) in pores are second
phases.
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This is a liquid liquid two phase system. On the left the oil and
water phases have segregated back and have the minimum surface area
interface possible. Physically mix the oil and water together and
you get the emulsion on the right. It is called an oil in water
emulsion simply because there is more water to start with so it
gets to be the continuous phase. Without a surfactant, the emulsion
will break down and the oil and water layers will reform. This
process is fast because the viscous is too low to create a barrier.
Surfactants raise the barrier and kinetically stabilize the
emulsion.
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The block copolymers used to template silica, silsesquioxane or
metal oxide growth are basically a Class 1B system. They are lumped
in class 2 in this course, but in the future I will probably move
them to this lecture. The triblock above has hydrophilic and
hydrophobic phases. Unhydrolyzed monoemr will dissovle in the
hydrophobic phase but as it hydrolyzes, it becomes hydrophilic
enough that it migrates into the hydrophilic phase where it
condenses into an amorphous structure tempalted by the 3-D
structure of the surfactant. Note if you start with the metal salt
hydrates they will go into and stay in the hydrophilic phase. We
will talk more about these templated materials in the lectures to
come, because they are the closet akin to biohybrids that we have
to date.
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