Lecture 21, p 1
Lecture 22
Freezing/boiling Point Elevation/depression Supercooling/superheating
Midterm review
Gas p1 T
p
Phase Diagram:
p3
p2
Solid Liquid
Lecture 21, p 2
So far, our liquid and solid m(T) curves have been
independent of pressure. We justified this with the
fact that solids and liquids are nearly incompressible
(which is true). This means that Tfreeze should not
depend on pressure. So:
Why is the line that separates the
liquid and solid phases not vertical?
The reason is that, although they are incompressible,
the volumes of the liquid and solid are not the same.
Most substances expand when they melt.
Suppose the volume change per mole is DV (which
means DV/NA per particle). Thus, (during melting)
when a particle moves from solid to liquid, work is done by it (it’s expanding):
W = pDV/NA. This is a positive contribution to the liquid’s chemical potential,
and it increases with pressure. If you look at the chemical potential graph
above, you’ll see that this causes Tfreeze to increase with pressure.
Phase Transitions and Volume Change
Gas
T
p Solid Liquid
T
m Tfreeze
L
S
Lecture 21, p 3
Water is Unusual
The typical phase diagram The H2O phase diagram
Most materials freeze if you push hard enough, but water melts!
This results from the fact that water expands when it freezes (ice
floats). Consequences:
Fish can live in wintry lakes, because they don’t freeze solid.
Ice is slippery when you skate on it … NOT!
It’s true that ice is slippery, but not for this reason - the pressure
required is too large. Here’s an article about it:
Gas
T
p Solid Liquid
http://people.virginia.edu/~lz2n/mse305/ice-skating-PhysicsToday05.pdf
T = 0.01° C
p = 0.006 atm
Lecture 21, p 4
Lowering the density of the gas lowers its chemical
potential curve mG. This will move the boiling transition to
lower temperature. This is the reason water boils at lower
T at high altitude.
We can similarly lower the mL curve by lowering the density
of the molecules in the liquid. This will lower the freezing
temperature of the liquid.
Example: Putting salt on ice lowers the melting point. Why?
The salt dissolves in the liquid, lowering the density (and thus
m) of the remaining liquid H2O. The salt does not easily
penetrate the solid ice, so has little effect on its m.
This illustrates a general principle: Dissolving substance A in substance B lowers the
chemical potential. If the chemical potential weren’t lowered, it wouldn’t dissolve!
Note: The density argument we made above isn’t always the important point.
Sometimes, the energy change is also important (even dominant).
http://antoine.frostburg.edu/chem/senese/101/solutions/faq/thermo-explanation-of-freezingpoint-depression.shtml
Variation of Freezing/boiling Temperatures
T
m
G
L
S
Lecture 21, p 5
Freezing point depression/Boiling point elevation
Solid ms Liquid mL
Gas mg
T
Tfreezing
Tboiling
Lowering the density of the gas lowers the
chemical potential curve mg .
We can similarly lower the mL curve by
lowering the density of the molecules in
the liquid.
mg
ms
mL
http://antoine.frostburg.edu/chem/senese/101/solutions/faq/why-salt-melts-ice.shtml
Lecture 21, p 6
Freezing point depression/Boiling point elevation
T
Tfreezing
Tboiling
Lowering the density of the gas lowers the
chemical potential curve mg .
We can similarly lower the mL curve by lowering
the density of the molecules in the liquid. How
do we lower the density of molecules?
Replace them with other sorts of molecules
(It is only the molecules of the same species
as the solid that count toward equilibrium).
There are very many solutes which:
•Dissolve easily in the liquid phase
•Don’t fit well at all in the crystal
•Have very low vapor pressure (absent from gas)
These have almost no effect on H2O’s mg or mS.
•anti-freeze
•salt on roads
•sugar would work too, but
•doesn’t have as many molecules/kg
•costs more
•would leave a sticky mess!
Solid ms Liquid mL
Gas mg
Liquid with solvent
mg
ms
mL
mL,solvent
T’boiling
T’freezing
They always lower ml
(stabilize liquid in each case).
So they lower Tf and they raise Tb
Physics 213: Lecture 13, Slide 7
FYI: Quantitative Freezing Point Depression, H2O
At low solute concentration, n= N/V, the only effect of the solute on m is via getting more S when the solvent volume increases.
(too few solutes to interact, solute-H2O interaction doesn’t change when you get more H2O)
We can calculate the effect exactly via state counting! This result does not depend on the type of solute particle!
At higher solute concentrations other terms (solute-solute interactions) also matter
Adding 1 molecule of water increases the solution volume V by dV=3*10-29 m3.
•So V available to each solute molecule increases by a factor (1+dV/V).
•So its S increases by k ln(1+dV/V)= k dV/V
•This happens to nV molecules.
•So DS = knV dV/V = nkdV.
•At 1 Molar solute, n=6*1026/m3: DS = nkdV = 2.5*10-25 J/K
DS of freezing = Latent Heat/T= (6000 J/Mole) /273K ~ 22 J/K-Mole, ~3.7 10-23 J/K-molecule
•So a 1M solute increases the melting DS by ~ 0.7% (2.5*10-25 / 3.7 10-23 )
•To keep the TDS term in DG balancing DH at TF,
TF must drop by about 0.7%/M or 1.9 K/M (works well experimentally)
Obtained via plain old state counting, and minimizing G in equilibrium.
How it works (exact for dilute solutions):
A solvent molecule entering from another phase
gives extra V for each solute molecule to roam in.
That increases the solute’s S, reduces DG= DU+pDV-TDS.
Smaller DG on adding a solvent particle means reduced m of solvent.
Lecture 21, p 8
ACT 1: Boiling Temperature
T
m
G
L
S
What does the addition of salt to liquid water do
to its boiling temperature?
A) Raises the boiling temperature
B) Lowers the boiling temperature
C) Does not change the boiling temperature
Lecture 21, p 9
Solution
T
m
G
L
S
Adding salt to the liquid lowers the liquid’s m,
(because it lowers the H2O density) raising the
boiling temperature.
However, we must be careful. What does the
salt do to the gas’s chemical potential? In this
case, salt does not evaporate easily (it has a very
low vapor pressure), so it has a negligible effect
on mG. If we were to dissolve a more volatile
substance (e.g., alcohol) in the liquid, the answer
might be different.
What does the addition of salt to liquid water do
to its boiling temperature?
A) Raises the boiling temperature
B) Lowers the boiling temperature
C) Does not change the boiling temperature
Lecture 21, p 10
Supercooling & Superheating
Solid ms Liquid mL
Gas mg
T
Tfreezing
Tboiling
mg
ms
mL
Tsc
Supercooled
liquid
If we cool a liquid to Tfreezing, normally it will
freeze to lower its free energy.
However, if there are no nucleation sites, it
is possible to “supercool” the liquid well
below the freezing temperature.
This is an unstable equilibrium.
What happens when the system suddenly
freezes?
Lecture 21, p 11
Solution
If we cool a liquid to Tfreezing, normally it will
freeze to lower its free energy.
However, if there are no nucleation sites, it
is possible to “supercool” the liquid well
below the freezing temperature.
This is an unstable equilibrium.
What happens when the system suddenly
freezes?
The free energy drops.
This “latent heat” is suddenly released.
It is similarly possible to superheat a liquid
above its boiling temperature; adding
nucleation sites leads to rapid (and often
dangerous!) boiling.
Solid ms Liquid mL
Gas mg
T
Tfreezing
Tboiling
mg
ms
mL
Tsc
Supercooled
liquid
Superheated
liquid
Physics 213: Lecture 13, Slide 12
Supercooling/superheating Demos
Liquid water can be
•heated above 100°C
• http://www.animations.physics.unsw.ed
u.au/jw/superheating.htm
•Cooled well below 0°C
• http://www.youtube.com/watch?v=13unrtlvfrw
Why does the water only partly boil or freeze (slush)?
What is T of the leftover water?:
Boiling: 100°C
Freezing: 0°C
Physics 213: Lecture 13, Slide 13
Supercooling/superheating Demos (2)
Freezing: warmed to 0°C.
The molecules U* dropped as they joined the ice,
releasing U* that warmed things up to 0°C
At which point freezing stopped
leaving slush.
*To be precise, it’s U+pV (enthalpy, H) here at constant p
Boiling: cooled to 100°C.
U+pV (enthalpy, H) increased as molecules joined the gas,
soaking up H from surroundings, cooling them to 100°C
At which point boiling stopped
leaving some liquid.
Lecture 21, p 16
8. [30%] On a planet not entirely unlike earth, the ratio of the partial pressure of N2
to that of O2 equals 1 at an altitude of 1 km: pN2/pO2 = 1. Assuming that T = 200K,
and the gravitational constant is 5 m/s2, what is the ratio pN2/pO2 at an altitude of 0
km. (Hint: You can use the Boltzmann distribution to calculate the law of
atmospheres.)
a. pN2/pO2 = 0.90
b. pN2/pO2 = 0.99
c. pN2/pO2 = 1.00
d. pN2/pO2 = 1.01
e. pN2/pO2 = 1.10
9 [55%]. Assuming that the total number of gas particles is constant, what will
happen to the density of the N2 at zero altitude as the temperature drops from 200 K
190K.
a. the density will decrease
b. the density will stay the same
c. the density will increase
Lecture 21, p 17
A Cu sphere of mass 0.5 kg is thermally linked by three wires to a large
thermal reservoir at 0 °C. The length of each wire is 1m and the radius
is 1 mm. The initial temperature of the sphere is 100 °C. The specific
heat of Cu is 386 J/kg-K. The heat conductivity of copper is κ=401
W/m-K.
2. [45%] How much time will it take for the temperature of the Cu
sphere to decrease from 100°C to 99.9°C ?
a. 10 s
b. 50 s
c. 100 s
d. 10 μs
e. 50,000 s
3. [80%] Assume now that we cut two out of three wires connected
the Cu sphere to the Cu block. How will the time required to cool
the sphere from 100 °C to 99.9 °C change?
a. The time becomes longer by a factor of 9.
b. The time becomes shorter by a factor of 3.
c. The time becomes longer by a factor of 3.
Lecture 21, p 18
ground state, no degeneracy
excited state, degeneracy = 2
ground state
E = ε + μB, “μ opposite B” E = ε – μB, “μ along B”
Consider a collection of atoms, all with a single ground state, and a doubly degenerate first excited
state.
5. [65%] Now we apply a magnetic field which happens to split the first excited level into two (non-
degenerate) states, one of which has the energy ε + μB (“μ opposite B”), the other with energy ε – μB
(“μ along B”), as shown. At T = 200 K we observe that the relative fraction of atoms with spin up to
those with spin down is: F = N(“μ opposite B”)/N(“μ along B”) = 0.1. What is μB?
a. 0.02 eV
b. 0.46 eV
c. 0.8 eV
6. [70%] Now we increase the temperature T (a lot).
What will happen to F = N(“μ opposite B”)/N(“μ along B”)?
a. F → 1
b. F → ∞
c. F → 0
d. F stays the same
e. Cannot tell from the information given
7. [47%] As the temperature T becomes very large, what is the dimensionless entropy for a system
with N of these atoms (still with small magnetic field on)?
a. N ln 2
b. N ln 3
c. cannot be determined from the information given
Lecture 21, p 20
Supplement: Semi-quantitative Analysis of Freezing Point Depression
We can figure out how big the effect is if we know how much the solute reduces water’s m. Let’s estimate by assuming the solute is ideal, and counting states.
Adding 1 molecule of water increases the solution volume V by dV=3*10-29 m3. (You can check.)
• So V available to each solute molecule increases by a factor (1+dV/V).
• So its entropy (s) is changed by ln(1+dV/V)= dV/V
• If the solute concentration is n=N/V, this happens to nV molecules.
• So the net effect on their total s is ds = nV dV/V = ndV.
• At 1 Molar, n=6*1026/m3: ndV=6*1026/m3 *3*10-29 m3= 1.8*10-2
• So when a water molecule is added there’s an extra ds = 1.8*10-2
• Per water molecule: dS = 2.5*10-25 J/K. Per mole: extra DS= 0.15 J/K
DS of freezing = Latent Heat/T= (6000 J/Mole) /273K ~ 22 J/K-Mole.
• So a 1M solute increases the melting DS by ~ 0.7%.
• To keep the TDS term in DG balancing DH at TF,
TF must drop by about 0.7%/M or 1.9 K/M
• The real number from a table is about 1.86 K/M.
We got that by going back to plain old state counting, and remembering to minimize G in equilibrium.