5.5 Surfaces in One-Component Systems 229
The surface of a cavity inside a liquid acts like the surface of a droplet, exerting
force that tries to reduce the size of the cavity. It reduces the pressure in the liquid
at the surface of the cavity while increasing the pressure inside the cavity. The vapor
pressure of the liquid is decreased below that of a planar surface.EXAMPLE5.14
Show that the vapor pressure inside a spherical cavity is given byln⎛
⎝Pvap
Pvap(p)⎞
⎠−^2 V(l)
mγ
rRT
(5.5-17)Solution
We can repeat the derivation of Eq. (5.5-14), the Laplace equation, with the role of liquid and
gas reversed. The result is that the pressure of the gas (inside the cavity) is greater than that
of the liquid (outside the cavity):P(g)−P(l)P(inside)−P(outside)
2 γ
r
We have already obtained a relation between the total pressure and the vapor pressure,
Eq. (5.3-18):P 2 P 1 exp(
Vm(P 2 ′−P 1 ′)
RT)whereP′represents the total pressure andPrepresents the vapor pressure. Since the pressure
in the liquid is smaller, and vapor pressure of the liquid is obtained by substitutingP(g)−P(l)
forP 2 ′−P′ 1 , givingPvapPvap(p)exp(
−Vm(P(g)−P(l))
RT)
P(p)vapexp(
−
2 Vmγ
rRT)Exercise 5.16
Find the vapor pressure of water at 298.15 K inside a spherical cavity with diameter 0.0200 mm.Because the lessening of the vapor pressure at the surface of a cavity is greater for a
smaller cavity, the formation of a cavity requires a higher temperature than vaporizing
the liquid from a planar surface. For this reason, a liquid can often be superheated
well above its normal boiling temperature if its container is smooth and there are no
particles in the liquid at which cavities can begin to form. The superheated liquid can
suddenly boil (“bump”) when the metastablesuperheated liquidfinally begins to form
cavities. This effect has been observed when heating water in a microwave oven if the
water is contained in a vessel with a smooth inner surface. In an organic chemistry
laboratory “boiling stones” with rough surfaces are often placed in a liquid to avoid
superheating.