thermodynamics - school of physics and astronomygja/thermo/lectures/lecture16.pdf...thermodynamics...
TRANSCRIPT
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...Thermodynamics
Third Law of Thermodynamics
Entropy, and its derivatives, go to zero as T → 0.
Zero heat capacity, thermal expansion.
Entropy as counting states.
“T → 0” means thermal energy is close to quantum energy.
diatomic ideal gas:
Entropy as information
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Gibbs phase rule
How much information is needed tospecify system?
...equivalently...
How many independent variables (F)does a system have?
F − 2 = C − NP
C: Chemical species - reactions
NP : Number of phases present
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What must be given to define the state: Gibbs phase rule
F=C+2-NP
Single phase water: F = 1+2-1 =2. P and T must be specified.
Ice/water mix F = 1+2-2 =1. Specifying P defines T.
Triple point F = 1+2-3. no freedom, unique P,T.
Critical point No freedom, unique P,T =⇒ P=3. (!)
Gaseous O2, H2 and H2O: F = 3+2-1.Leaves four d.o.f, e.g. T, P, NO2 NH2
...+reaction 12O2 + H2 ⇔ H2O F = 2+2-1,
Leaves three d.o.f.(Assuming known reaction constant K, q.v.).
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Paul Ehrenfest (1880-1933)
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Ehrenfest’s order of phase transitions
g1 = g2
First order: discontinuous change of state variables (e.g. s or v)
∂g1∂T6= ∂g2∂T
Second order: continuous change of state variables, but discontinuousderivatives (e.g. cv , K , β)
∂g1∂T
=∂g2∂T
∂2g1∂T 2
6= ∂2g2∂T 2
Third order: continuous change of state variables and derivatives.
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Discontinuous ≡ 1st order transitions
Isothermal process traverseX’Y’ At the phase boundary.
g1 = g2 always . . .
For first order, derivatives change...
−(∂g1∂T
)P
6= −(∂g2∂T
)P(
∂g1∂P
)T
6=(∂g2∂P
)T
s1 6= s2 and v1 6= v2
Discontinuous transition ≡ 1st order
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Second derivatives?
Isobaric Heat Capacity T(∂s∂T
)P
= T(∂2g∂T 2
)P
Thermal Expansivity 1V
(∂V∂T
)P
= 1V
(∂2g
∂TP∂PT
)Isothermal Compressibility −1
V
(∂V∂P
)T
= −1V
(∂2g∂P2
)T
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The ‘discontinuities’ at continuous phase changes
In a second order transition
−(∂g1∂T
)P
= −(∂g2∂T
)P
and
(∂g1∂P
)T
=
(∂g2∂P
)T
∆S = 0 means no latent heat. ∆V = 0 means no volume change.
S and V are anyway related by(∂s∂P
)T
Maxwell= −
(∂v∂T
)P
No latent heat or volume change: same internal energy dU = TdS − PdV
Clausius Clapeyron = 0/0.
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What sort of thing?
Two types of transition look like “second order”
“Critical fluctuation” is where regions of the system fluctuate into theother phase in an uncorrelated way.e.g. ferromagnet.
“Coexistence” is where one phase the system is effectively two-component.e.g. Bose condensate.
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The Ehrenfest equations
Equivalent of Clausius-Clapeyron for second order boundary.Consider entropy at points (T ,P) and (T + dT ,P + dP) on phase boundary.No change in s or v .
at A s1(T ,P) = s2(T ,P)
at B s1(T + dT ,P + dP) = s2(T + dT ,P + dP)
use a Taylor expansion on B(∂s1∂T
)P
dT +
(∂s1∂P
)T
dP =
(∂s2∂T
)P
dT +
(∂s2∂P
)T
dP
Identify heat capacity cP , thermal expansion β: “first Ehrenfest equation”:(dP
dT
)pb
=cP,1 − cP,2
Tv(β1 − β2)=
CP,1 − CP,2
TV (β1 − β2)
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Second Ehrenfest equation
“Second Ehrenfest equation”(dP
dT
)pb
=β2 − β1κ2 − κ1
Similar derivation starting from v1 = v2Slope of transition line relates to ∆β, ∆κ, ∆CP .
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Fluctuations, Instability and Scaling Laws
In critical region close to the transition, ±∆Tcrit around Tc
e.g. Heat Capacity
CV ∝ (T − TC )−α
e.g. correlations between magnetic spins
< Si .Sj >∝ r−ν
Power Law dependence implies there is no characteristic scale.Universality: conjecture that α, ν are independent of material.In Economics and Ecology, as in Physics, forthcoming transitions oftencharacterized by big fluctuations.
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Giraffe (Phase coexistence)
Animal skin patternscome from phaseseparation betweenpigmented andnon-pigmented cells.
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Percolation: cutting a chicken wire
How many random bonds give aconnection?Imagine links are wires- discontunity in conductivity..
EM Quiz: infinite square/cubic lattice of
resistors, what is the resistance between
opposite corners?
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Ferromagnet
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Ising Ferromagnet
U = ε∑i ,j
σiσj
Equation of state: M = (T − Tc)β and
χ = dMdB =
(C
T−Tc
)γMACRO: zero magnetisation to finitemagnetisation
MICRO: transition from aligned spins torandomly oriented spins.(∂M∂T
)B,P
massive near transition.
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Liquid Helium
https://www.youtube.com/watch?v=2Z6UJbwxBZI
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Liquid Helium
At Tλ = 2.2 K, on cooling (He I) to“superfluid” (He II)
Only for 4He (Bosons)
Finite fraction of atoms in same(ground) quantum state (S=0).
He II phase: no viscosity.
Peak in CP at transition.
Looks like a λ, hence Tλ.
Heat capacity continuous: third order
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Superconductivity
Heat capacity of In: nosingularity
No latent heat
2nd order Transition,
Below Tc = 3.4K electrical resistance iszero.
“Two component model”
Electrons couple to form “Cooperpairs” (bosons).
Finite fraction of electrons (N1) inground state (S=0)
Why is the average R zero?Consider resistors in parallel:
1
R=
N1
R1+
N2
R2
R1 = 0 =⇒ R = 0
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Superconductivity suppressed by
High temperature
High field
High current
Type I excludes all magneticfields
Type II allows some magneticfield
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