Critical points

The critical point, discovered in 1822 by Charles Cagniard de la Tour ^[1][2] , is a point found at the end of the liquid-vapour coexistence curve (the red point shown on the pressure-temperature plot on the right). At this point the temperature is known as the critical temperature ${\displaystyle (T_{c})}$ and the pressure is known as the critical pressure ${\displaystyle (P_{c})}$. For an interesting discourse on the "discovery" of the liquid-vapour critical point, the Bakerian Lecture of Thomas Andrews makes good reading ^[3]. Critical points are singularities in the partition function. In the critical point vicinity (Ref. ^[4] Eq. 17a)

${\displaystyle \left.{\frac {\partial P}{\partial n}}\right\vert _{T}\simeq 0}$

and

${\displaystyle n\int _{0}^{\infty }c(r)~4\pi r^{2}~{\rm {d}}r\simeq 1}$

For a review of the critical region see the work of Michael E. Fisher ^[5]

"... Turning now to the question of specific heats, it has long been known that real gases exhibit a large ``anomalous" specific-heat maximum above ${\displaystyle T_{c}}$ which lies near the critical isochore and which is not expected on classical theory..."

also

"... measurements (Ref. ^[6] ) of ${\displaystyle C_{V}(T)}$ for argon along the critical isochore suggest strongly that ${\displaystyle C_{V}(T)\rightarrow \infty ~{\rm {as}}~T\rightarrow T_{c}\pm }$. Such a result is again inconsistent with classical theory."

Thus in the vicinity of the liquid-vapour critical point, both the isothermal compressibility and the heat capacity at constant pressure diverge to infinity.

Liquid-liquid critical point[edit]

Solid-liquid critical point[edit]

It is widely held that there is no solid-liquid critical point. The reasoning behind this was given on the grounds of symmetry by Landau and Lifshitz ^[7]. However, recent work using the Z2 potential suggests that this may not be the last word on the subject. ^[8].

Tricritical points[edit]

• Robert B. Griffiths "Thermodynamics Near the Two-Fluid Critical Mixing Point in He³ - He⁴", Physical Review Letters 24 715-717 (1970)
• Lech Longa "On the tricritical point of the nematic–smectic A phase transition in liquid crystals", Journal of Chemical Physics 85 pp. 2974-2985 (1986)

Critical exponents[edit]

Main article: Critical exponents

Yang-Yang anomaly[edit]

Main article: Yang-Yang anomaly

See also[edit]

• Binder cumulant
• Law of corresponding states

References[edit]

Related reading

• M. I. Bagatskii and A. V. Voronel and B. G. Gusak "", Journal of Experimental and Theoretical Physics 16 pp. 517- (1963)
• Robert B. Griffiths and John C. Wheeler "Critical Points in Multicomponent Systems", Physical Review A 2 1047 - 1064 (1970)
• Michael E. Fisher "The renormalization group in the theory of critical behavior", Reviews of Modern Physics 46 pp. 597 - 616 (1974)
• J. V. Sengers and J. M. H. Levelt Sengers "Thermodynamic Behavior of Fluids Near the Critical Point", Annual Review of Physical Chemistry 37 pp. 189-222 (1986)
• Kamakshi Jagannathan and Arun Yethiraj "Molecular Dynamics Simulations of a Fluid near Its Critical Point", Physical Review Letters 93 015701 (2004)
• Kurt Binder "Computer simulations of critical phenomena and phase behaviour of fluids", Molecular Physics 108 pp. 1797-1815 (2010)

Books

• H. Eugene Stanley "Introduction to Phase Transitions and Critical Phenomena", Oxford University Press (1971) ISBN 9780195053166
• Cyril Domb "The Critical Point: A Historical Introduction To The Modern Theory Of Critical Phenomena", Taylor and Francis (1996) ISBN 9780748404353