Circumnavigating the Critical Point

​
The pressure-temperature phase diagram for water illustrates the concept of state functions and demonstrates how to go from the liquid phase to the vapor phase (or the reverse) without a phase change by circumnavigating the critical point, which is the highest temperature and pressure where two distinct phases exist (647 K, 22.1 MPa for water). Drag the black dot to change pressure and temperature; its range is limited, from
-3
10
to
3
10
MPa and from the triple point to 720 K, so that the volume changes can be more easily displayed. The liquid, vapor, and supercritical regions are labeled, but no definite boundaries exist between these regions. The transitions are continuous when going around the critical point, but a phase change is observed when crossing the phase boundary. The piston and cylinder represent the log of the volume (calculated from the Peng-Robinson equation of state), so that the large differences in volume between gas and liquid can be visualized. Fluid with higher density is shown darker.

Details

The volume and density are calculated from the Peng–Robinson equation of state:
P=
RT
V-b
-
a
2
V
+2Vb-
2
b
,
a=0.457
2
R
2
T
c
P
c
2
1+κ1-
T/
T
c

,
b=0.0778
R
T
c
P
c
,
κ=0.375+1.54ω-0.27
2
ω
,
where
P
is pressure (MPa),
T
is temperature (K), the subscript
c
represents the critical property,
V
is the molar volume (
3
cm
/mol
),
R
is the ideal gas constant,
a
,
b
, and
κ
are Peng–Robinson constants, and
ω
is the acentric factor.
The molar density is
ρ=1/V
(
mol/
3
cm
).
A screencast video at[1] shows how to use this Demonstration.

References

[1] Circumnavigating the Critical Point[Video]. (Dec 16, 2020) www.learncheme.com/simulations/thermodynamics/thermo-1/circumnavigating-the-critical-point.

External Links

Phase Behavior on a Pressure-Volume Diagram
Single-Component P-V and T-V Diagrams

Permanent Citation

Rachael L. Baumann, John L. Falconer, Megan Maguire, Nick Bongiardina
​
​"Circumnavigating the Critical Point"​
​http://demonstrations.wolfram.com/CircumnavigatingTheCriticalPoint/​
​Wolfram Demonstrations Project​
​Published: September 4, 2014