Low-Temperature Heat Capacity of Hydrogen Molecules
Low-Temperature Heat Capacity of Hydrogen Molecules
Hydrogen is the lowest boiling molecular species, remaining a gas down to 20K. At and above room temperature, , the rotational degree of freedom is fully excited; thus the rotational contribution to heat capacity approaches its equipartition value, per mole. Owing to the exceptionally small moment of inertia of , rotation becomes inactive at temperatures below about 50K. However, the heat capacity behaves anomalously as the temperature is lowered. This anomaly was first explained by Dennison in 1927. Since is a homonuclear molecule, only half of its rotational states are accessible. In the singlet nuclear-spin state, known as parahydrogen (p-) only even- rotational states are accessible; in the triplet nuclear-spin state, known as orthohydrogen (o-) only odd- rotational states are accessible. The molecular partition functions representing the rotational and nuclear spin degrees of freedom are given by
H
2
T≳300K
R
H
2
H
2
H
2
J
H
2
J
q
ortho
Σ
Jodd
-J(J+1)Θ/T
e
q
para
Σ
Jeven
-J(J+1)Θ/T
e
The rotational energies are given by =J(J+1)/2I with -fold degeneracies. It is convenient to define the rotational characteristic function , equal to 87.57 for and 65.70 for HD. The factors 1 and 3 represent the degeneracies of the para and ortho nuclear spin states, respectively.
E
J
2
ℏ
(2J+1)
Θ=/2Ik
2
ℏ
H
2
The rotational contribution to heat capacity per mole can be calculated using (T)=R. This can be plotted for o-, p- and a 3:1 mixture which exists in hydrogen gas at room temperature. The two forms do not interconvert unless a catalyst, such as activated charcoal or platinum is present, so the 3:1 ratio will persist as the temperature is lowered. In the presence of a catalyst, the partition function can be represented by its equilibrium value =+, with the sum running over both even and odd . This will be reflected in a heat capacity (T) that reaches a maximum in excess of around . Para in the state, with a purity around 99.7%, can be obtained by cooling the equilibrium mixture down to 20K. (There also exist elaborate procedures for obtaining pure o-.)
rot
C
∂
∂T
2
T
∂logq
∂T
H
2
H
2
q
equi
q
ortho
q
para
J
rot
C
equi
2R
T≈40K
H
2
J=0
H
2
The isotopomer HD is a heteronuclear diatomic molecule, with the nuclear spin-molecular rotational partition function given by
q
HD
∞
∑
J=0,1…
-J(J+1)/T
Θ
HD
e
Θ
HD
The nuclear-spin degeneracy equals , where the spins of the proton and deuteron are and 1, respectively.
(2+1)(2+1)
I
P
I
D
I
1
2
You can select any combination of five heat-capacity curves over a temperature range. These can be identified using the tooltip.