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Critical behavior in fluids and fluid mixtures
19
Fluid Phase Equilibria, 14 (1983) lS-44 Elsevier Science Publishers B.V., Amsterdam-Printed
CRITICAL
BEHAVIOR
J. M. H. Levelt Thermophysics
in The Netherlands
IN FLUIDS AND FLUID MIXTURES
Sengers,
Division,
G. Morrison, National
and R. F. Chang
Bureau
of Standards,
Washington,
D.C. 20234
ABSTRACT The presence of large fluctuations near a critical point leads to thermodynamic anomalies not present in classical, i.e., analytic equations, such as, that of van der Claals. We introduce the concepts of universality, critical exponents, scaling laws, "field" and "density" variables, "strong" and "weak" directions. Experimental evidence for the presence of nonclassical critical behavior in fluids and fluid mixtures is presented. A scaled thermodynamic potential represents the thermodynamic data of steam, ethylene and isobutane accurately. It is valid up to 1.07 T,, and within ?30% from pc. Methods for joining it to an analytic equation are discussed. The generalization to a nonclassical description of fluid mixtures is described, and applications are given. The engineer may require the nonclassical description in custody transfer, design of supercritical power cycles and supercritical extraction. The classical approach is used here to explain peculiarities of dilute mixtures recently reported by several experimenters.
INTFODUCTION The modern years, amongst point
theory
of critical
has crystallized theoreticians
prize,
about
forms
systems.
a decade
ago,
a mathematical parameter,
of the large
compressibility.
Haals
equation
fluctuations,
for fluids they
are
consequences
of these
fluctuations
is that
interparticle fluids)
that
and
interactions;
into
meter.
Non-ionized
0378-3812/83/$03.00
ranges
no longer
phenomena
character
d of the system fluids
class,
and fluid
larger
on the precise
details
have a character
characterized
mixtures
these that are
than the in most
of the
of universality;
different by only
near normal
0 1983 Elsevier Science Publishers B.V.
ignore
anomalies
(as they are
and the dimensionality
because
of the critical
of space much
in the many
point
such as the van der
for magnets,
character
introduced the Nobel
of the fluctuations
those critical
are short-ranged
depend
granted
descriptions,
The striking
over
of the critical
approach
near a critical
theory
to deal with
one universality
the dimensionality
classical
the mean-field
critical
the nature
the effects
predominant
If the forces
is, they are of identical
be grouped
Since
fluctuations.
will
the past twenty has been reached
he was recently
for describing
become
inadequate
spacings.
regarding
and for which
they extend
the phenomena
molecular
which
during
consensus
The renormalization-group
basis
of the order
developed
that a broad
and exnerimentalists
in many different
by Wilson
behavior,
to the point
systems
that
can
two parameters,
n of its order critical
points
parabelong
20 in the
universality
houses
uniaxial
disorder
phase
detailed
and
systems,
paper
show
critical from
theoretical
one-component
to
fluid
component some
on
the
a recent
CRITICAL
The cal
Helmholtz
P*=P/Pc
reduced
pressure terms
of
of
dilute
related,
of
the
departures will how
critical
have
be the
anomalies
been
extended
classical
paper
least
the
("scaled")
the
mixtures, at
characteristic
occur,
anomalies
The
engineer.
pressure
van
density
reduced
der and
critical
and
quadratic
The linear
isochore. a
Pij
and
only
order,
the
shown
approach.
in one
will
and
close
an area
in part,
index
two-
with
in which
to
the
aT*=T*-1.
AP*, namely
reduced
there
interest
Eq.
(2)
the
scaled
(1)
density
absent
on
vapor
pressure
the
(1973), equation with
(Ao*)~
because
right-hand curve
of
con-
terms
have
Eq.
P,,*(T) and
the
(1)
rearrangement
of
state:
a scaling
is a function
temperature
the
the
side
x=(~T*)/(ap*)~ of
the
of
a slight of
T*=T/T,, of
value;
density-dependent
terms
the
and
to derivatives
alone
is an example by
reduced
are
classicritical
,
...
related
the
write
a critical-point
Sengers for
+
we may
for
at
c denotes
{1+41/P30)x)
if divided
the
potential
be expanded
Thus
lowest-order
by Levelt
= P30(AP*)3
variable,
p*=p/pc, constants,
the
chemical all
+ P30(P*_l)3
density
expression
the can
temperature.
density-independent
As
and
the
in the
"scaled"
difference
are
and
Waals,
pressure,
point;
= P*-Pd*(T*)
two)
with
critical
such This
FLUIDS
the of
the
AP*
than
that
the
(1) yields
a~*=~*-1
the
(T*-lli + Pll(P*-l)(T*-1)
Eq.
pressure
to
the
working
descriptions
a
of
"scalina".
demonstrated
accuracy,
contrasted
of the
interest,
energy,
as
is the
to
actual
scaled
and
behavior
of
of criticality;
critical
Here
concern
into
of
nature
be
yielded
behavior
departures
then
also order-
behavior free
retained_
represent,
these
which
temperature;
linear
ditions been
at
of
series
‘* = ’ + I ‘oi the
way
be explained
critical
such
in Taylor
where
The
It will
with
have
show
The
these
experimental
IN ONE-COMPONENT
critical
equations,
point
transformed
been
name
indeed
systems.
in which
have
to within
do
class
alloys
methods
by the
mixtures
which
A-B
thermodynamic
goes
Ising-like
model,
and
extraction.
BEHAVIOR
Classical
also
fluid
Ising
critical
examples.
surge
in supercritical
the
ranges
be addressed are
of
Practical
will
fluids
been
the
fluids.
will
remarks
has
of
mixtures
question
renormalization-group
for
and
describe,
of
The
and
predicted
concepts that
3-dimensional antiferromagnets,
description
fluids
theory,
in a number
equations
The
which
anomalies
the and
description
that
classical
shown
of
transitions.
accurate
Ising-like will
class
ferromagnets
of
x=*T*/(~p*)~.
.
(2)
law: only
the one
From
reduced (rather
Eq.
(2)
21 On the critical isotherm where
we derive the following asymptotic power laws. AT*=O and PgP c, we have: lAP*j=IP*-l/ = P30jA~I &, with 6=3
.
(3a)
On the critical isochore, where Ap*=O, we have (aP*/ap*),, = P,, IAT*I~,
with r=l
.
(3b)
This equation implies that the compressibility
KT, which is proportional to
(aP*/aP*)T, diverges as IAT*j-', which is a strong divergence.
The expansion
coefficient CXP and the specific heat at constant pressure Cp diverge strongly, like KT, as follows from considerations
of thermodynamic
stability [see, for
instance, Rowlinson's book (1982)]. Coexisting densities are obtained by setting the pressure equal to the vapor pressure for AT*
=
The term in curly brackets in Eq. (2) is to be equal to
It follows that
(P,,~P~~)~AT*I'/~,
with
@l/2
.
(3c)
Finally, the analyticity of the Helmholtz free energy implies that the second derivative CV, the specific heat at constant volume, is finite.
Thus, on the
critical isochore,
r
D) P “field”
P
field’
Y
, “density”
T “field”
Fig. 1. Pressure versus density isotherms (----_), the critical isotherm (---), the critical isochore (------), the critical point (0) and the coexistence curve ( -) in (a) P-P space and (b) P-T space. The paths along which the critical exponents a, 8, y and 6 are defined have been indicated.
22 C *
=
V
/AT*I-~
with
Equations
(3a-d)
the
indicated
paths
Nonclassical
each
the
in
Figs.
critical
phase
producing fluctuation, curve
is
tions. 1900’s
flatter
can than
Scientists that
exponents
and
approach
and their
classical
values
along
lb.
that
critical
conditions,
because
two
phases
no longer
such
fluid
la
substantial
When the
they
critical
behavior phases
become
them.
(3d)
define
When coexisting in
.
a=0
of
can
low
transform
given
by the
curves
have
density
in
free
each
theory, have
indeed
an approximately
which
fluctuations energy
other
Consequently,
classical (1900)
the cost
into
be distinguished.
as Verschaffelt
coexistence
the
in
by spontaneous the
coexistence
ignores
known
since
cubic
shape,
fluctuathe
early
as
ETHYLENE, y
-T
hi’.
1 INDICATES
I _
1
I _
2
T-T,
01
.0.5 MlLLlBA
I
I
I
5
10
20
PC
labeled 1,2,3,4;were measured within +l% of Fig. 2. Four isochores of ethylene, (1980). Isothermal pressure differences the critical density by Hastings et al. between isochores 1 and 3, 2 and 4, and 2 and 3, are proportional to KT-~ and are The slopes of the straight lines provide plotted on a double-logarithmic scale. estimates of the critical exponent y.
23
1
_ ,p-0.521g/cm3 I
Cal/molK
Levelt
Sengers
showed
(1973,
1976).
The flattening
of the critical
lead to departures
from the classical
in the other
critical
instead
of
the value which
Most
known
volume,
the most
in argon
of 1976.
thermodynamic zero weakly
speed
to
the speed
of sound,
equations
of state,
Whether I
I
I
140
150
160
Fig. 3. The specific heat at constant volume of argon diverges weakly at the critical point, according to Voronel (1976). density
and as much
of 2% from Tc and 20% steam
from pc.
in the 50-parameter
constrained
tend to overshoot by a few degrees
steam
1980)
even
the critical
good-quality
and specific
multiparameter Webb and
exceeding
1% in
heat CR .in the range
the representation
et al.
temper-
C for Tc near room
lead to errors
instance,
not
at the critical
Rubin may
by Keenan
depends
equations
like that of Benedict,
used
as
(1979,
to pay atten-
equations
[See, for
equation
in
in classical
anomalies
Classical
point
as 25% in compressibility
namely "dip"
experimentally,
needs
nonclassical
ature
temperature;
This
and Kalyanov
the engineer
specifically
the approach
such as van der b!aals's,
on the application.
T, K
see his
point,
not present
of
in Fig. 4.
tion to these
1
heat at
has a non-
in super-critical
and displayed
predicts
the anomaly
of sound will
observed
by Erokhin
to
1900's.
indication
by Voronel,
]aT*lo".
has been repeatedly
130
theory
direct
at the critical
for instance
equal
As a consequence,
proportionally
measured
being
free energy
et
exponent
the early
Fig. 3 displays
CV measured review
in Fig. 2 of near-
of CV, the specific
the Helmholtz
analyticity.
than
since
5/4
by Hastings
nonclassical
divergence
constant that
to 5, rather
a fact
remarkably,
a weak
about
is shown
as measured
values
y exceeds
The critical-isotherm
6 is close 3, again
y equals
the compressibility
ethylene
(1980).
temperature
Thus the
the exponent
1 substantially
displays
critical al.
exponents.
exponent That
1.
studies
of this curve
and the depression
compressibility
/
in her historic
(1969).]
of Co of
24
l 653.23 ~666.23 A 673.23 x 698.93
500-
450
K K K K
J
-
c E _ u”
400-
350 -
I 25
I
30020
I 1 30 35 Pressure, MPa
I
40
45
Fig. 4. The speed of sound of supercritical steam according to measurements by Erokhin shows a minimum related to the weak divergence of C The full curves are predicted values according to a scaled equation by Leve Y‘t Sengers et al. (1983a). Densities
and
Consider variables
are
etc.,
are
P,".
are
property
strong
energy
U as
extensive
different intensive;
and
and,
they a
Wheeler
(1957)
Properties a density boundary
= (-l/v)(av/aP),
lb).
density.
a field,
These
constant
density
slope
the
are
the
of
or ap
of
with
the
being
constant
that
of
density
T,
S/V,
P,
first
type
terminology
of
of
thermodynamics of critical 4 He, developed superfluid
that
both
properties with
vapor
gives
like
respect
boundary the
are
intersects
strongly,
nonclassical
phase
U/Ni.
anomby
(1961).
hand,
a density and
The
in the
These
.
as
properties
= (l/V)(aV/aT),
diverge
other
classical
isochore path
of
such
phases.
"field",
the
that
V, Nl...
conjugate
in a direction
the
derivatives
is confluent
a
S,
properties
in coexisting
Fairbanks
derivatives On
In both
critical
and
variables
Their
fashioned after
Buckingham
descriptions.
along
who
KT
(Fig.
its
specific
second
by
KS=C-l/V)(aV/aP)S
of
the
mixtures
to
of
identical
and
constant
entiation
are
(1970)
respect
anomalies
phases.
like
with
nonclassical
weak
in general,
"density",
in multicomponent
Pippard
and
a function
in coexisting
is called
Griffiths alies
fields;
the
the
CV=(aU/aT)V
to a field
(Fig.
lb),
pressure results
curve.
and or
at
a path the
of
phase
in classical
description,
finite
derivatives
of
limiting Differ-
in classical
25 theory major
but produces distinction
the weak
exponent,
however,
performed
(constant
along which
anomalies
to be made
between
in nonclassical
critical
does not only depend
density-weak),
the critical
point
is approached.
ity shows a r-divergence
along
the critical
divergence Since,
along
however,
character
the critical this
isobar
"exponent
of the divergence
Thus,
is the of a critical
compressibil-
(Fig. la) but only a y/ii&
(both classically
and nonclassically).
does not affect
or weak),
is
but also on the path
the isothermal
isochore
renormalization"
(strong
This
The value
on the way the differentiation
constant
;
field-strong
theory.
exponents.
we will
the essential
not belabor
this point
further. Scaling
Laws
By far the easiest with
their
way to introduce
classical
counterpart,
reduced
chemical
potential
reduced
pressure
difference.
behavior
but the chemical
equation
of state with
lApi*/ = where
Dlap*16
h(x),
the nonclassical
The two quantities
potential
nonclassical
scaling
values
of all power
laws
compressibility the exponents
constants
and h(x)=l+x,
by letting
the functional
Since
before.
and the specific a and T cannot
in an
(4) classically.
B and 6 assume
their
form of h(x) appropriately
law, Eq. (4), can thus be seen as a compact
introduced
6 by the following
variable
Thus we write
,
law is obtained
and by choosing
The scaling
(see below).
is to begin
for the
than for the
dependent
variables.
B(AT*)/IA~*I"~
laws
have the same asymptotic
is the appropriate
o and T as independent
x =
scaling
this equation
AU*=~*-U~*(T*), rather
difference
B and D are two substance-dependent
The nonclassical
We write
Eq. (2).
the anomalous
heat can be obtained Indeed,
be independent.
from
behavior
"packaging"
of the
(4), it follows
they are related
that
to R and
relations:
2-a = .5(6+1); y = 8(6-l),
(5)
so that only two of the four are yielded
accurate
will
therefore
will
assume
values
not consider
theoretical
a = 0.110
* 0.0045
0.325
+ 0.0015
6=
(The exponent empty
unless
property
al will
these
estimates
y = 6=
region
1.241 ? 0.0020 4.82
the equation
shortly.)
of state
than those
A, = 0.498 t
theory
systems.
parameters;
and Zinn Justin
; .
(derived)
function
of Ising-like
as fitting
of Le Guillou
be introduced
other
Renormalization-group
exponents
exponents
a form for the scaling
is required:
the one-phase
; ;
independent.
for the critical
rather
has We
we
(1980). 0.020
; (6)
The scaling h(x)
should
law, Eq. (5), is
is specified.
The following
have no nonanalyticities
at the critical
point.
In addition,
in it is
26 desirable
that
for
thermodynamic
other
have
relations
these
et al. have
integrable
been
proposed,
an
higher-order
up*
= krsa
et
thermodynamic
function
variable"
two
obey
Eubank
in the
variables,
of a "contour
or all
et al.
one-phase
overcame into
variables r, raised
some
can
have
been
which
and
region
the
(1969),
All
of
are
not
difficulties physical
properties
are
to an appropriate
variable"
and
to
scaling
et al.
(1979).
these
be obtained hard
of the
by Vicentini-Missoni
(1969),
(1969)
expressions
requirements
that
instance, al.
Schofield
parametric
The
state
nonanalyticities
form.
so-called
analytic
for
closed-form
These
of
Goodwin
of a "distance
and
so that
functions.
(1969),
transformed.
products
integrable
equations
in closed
introducing are
be
Nonanalytic
fulfill.
Verbeke
h(x)
by
variables
written
as
fractional
power,
e as follows:
AT* = r(l-b202) AU*
= arBde(l-e2),
etc.
(7)
In
Fig.
5 we
of constant
4
I
I
‘/ !
e=o J
0 on
the
vapor,
coexistence
constant
+1
are
optimum
form
for
First
data.
represent prefer
fluids
not
the
seminal
and
Moldover
(1976)
the
only
in a small
asymptotic
critical
point.
of
laws
region Levelt
of
region
for
10-S
it to
in AT*.
are
valid the
Sengers
several
be of
Thus,
Hocken
around
estimated
found
most
demonstrated
(1961)
this
between
Furthermore,
Sengers
and
Secondly,
a property
experiment
that
equations
symmetry
possess.
in
state--we
form.
perfect liquid,
do
at
fluid
these of
only
not yet
describing all,
of the
nonanaly-
centered
a canonical
and
zero
all
(7) are
an equation
imply
vapor
of
of
Since
equals point,
Eqs.
side
A contour
shown.
neatly
point.
-1 on
liquid
curve.
variable
ticities
they
on the
critical
a equals
isochore,
r is also
distance
contours
fl; specifically,
the
this
several
critical
the
at the
Fig. 5. Parametric distance (r) and contour (.a) variables in the density-temperature plane for one-component fluids. The fulldrawn curves are contours of constant 0, some of which have been labeled by the appropriate 0 value. One contour of constant r (-----) is also indicated.
show
the
the
and
size
fluids, order
in order
to
of
27 apply
the scaling
choice those
of scaling
ideas we will variables
corrections
need
to asymptotic
and the use of the Wegner
Proper
scaling.
expansion
will
fulfill
goals.
Scaling
variables
The canonical of the
and Wegner
independent
direction
expansion
form we have variables
is singled
out,
preferred p=P*/T*
is the potential
and 7=-1/T*.
that of the phase
P=P*/T*
as a function
In the n-7 plane, Only one
transition
itself
sequently,
(Fig. 6).
one scaling
Con-
variable,
is chosen along this %" "weak" direction. The strong variable, intersect
If
u is chosen to IJ' the special direction.
it is chosen
at an angle
the T=Tc axis,
(Fig. 6),
aUIIHnetry between liquid
ii (which
equation;
(Up= 0)
Wegner
Fig. 6. Choice of independent scaling variables for one-component fluids, ut in the weak direction and ulr in the strong direction, in the plane of independent variables ;, T.
P=P i
reg
PSC
=
t-3
+Psc I_
ko
l”t12-a
+ P,,(A~)(AT)
. &rectfon-
as proposed
by
(1972) and worked
for fluids
by Ley-Koo
Green (1981),
out
and
we write
+ . . .
90(Uu/1Ut/CE)
+
go, g, are universal
In parametric
representation,
term.
The value
ak,l~~l~-~+*l
functions
gl(Up/Iutl~d)
of the scaling
g,, and g, are simple
of the ut in the first
the leading
P
,
The functions
exponent
part,
the
analytic!),
_
= *in + P,,(T)
a
latter
is not
the first
to-scaling
i
a classical
for the
relation
Including
in 7 and
is not to be
with
and a scaled
of a
regular
part
identified
and
The
P consists
Preg.
P(G,i)
vapor
is introduced.
potential part,
to
Wegner
correction
of the gap exponent
+
A,
is
is A, listed
uU/lutlBs.
in e2. higher
(8)
.
variable
polynomials term
,..
The
than
in Eq. (6).
that of In
28 the
regular
while
part
P,,
Applications
of
Expansion
the
(1980)
et al.
(1983a)
et al.
(1983)
range
the
potential,
of
to
been
used the
to represent heavy
1
the
is represented
asymmetric
as a polynomial
term
in T,
in Preq.
expansion
represent
for
PO(T
multiplying
Wegner
(8) has
et al.
The
of
is a constant
the
water;
applicability
.on around in a regi' equation
for
of
state
thermodynamic
critical
surface
and
by Levelt
the
case
of
the
of ethylene;
Sengers
steam
point
of steam; et al.
by Hastings
by Levelt
(1983b)
is indicated
Sengers
by Kamgar-Parsi for
in Fig.
isobutane.
7.
In
I
I
690 Y # z d k!
660
P
660
670
650
-24
640
-22 t
1
I
I
200
I
I
I
300 DENSITY,
400
I
650
b’,$
I
I
660
670
TEMPERATURE
(0)
units, (T*-1)
-0.005 The
Wegner
of 0.1% sound
the
0.07
in pressure
are
range
expansion
fitted
I
690
, K
(b)
Fig. 7. Range of applicability of in steam, (a) in P-p and scaling, reduced
I
I
660
is roughly
and
fits
the
level
the
p*
0.7
or better.
on the
the Wegner expansion, (b) in P-T space.
PVT
same
1.3
data
all
fluids
one
correction
investigated,
to namely
.
(9)
of these
Derivatives of a few
for
with
fluids
such
percent
to within
as CP,
or better
Cv and (Figs.
their the
accuracy
speed
4, 8,
9).
of The
29
I
500_
0 22.5651 v 23.5360 A 24.5166
MPa MPa MPa
I
I Sirota’s temperature scale lowered
400 Y
2
2 .
300 -
0”
x
Density,
kg/m3
Fig. 8. Prediction of the specific heat Cp of steam by the scaled equation with one Wegner correction-to-scaling, compared with the CP data measured by Sirota. After Levelt Sengers et al. (1983a).
0 640
.’
660
I
660
Temper0ture.K
Temperature.K
Temperature. K
9. Prediction of the specific heat Cv of steam by the scaled equation with Fig. one Wegner correction term, compared with the Cy data measured by Amirkhanov. After Levelt Sengers et al. (1983a).
30 Wegner
expansion
quality
thus
thermodynamic
gives data
a quantitatively of
pure
correct
fluids
in the
representation
critical
of
high-
region.
Crossover The
engineer
in a limited and
scaled
have
some
ones
to
solutions
of
co2.
functions these
Recent f for
was
able
energy
the
of
C
V
proved
reported
Helmholtz
of
for
steam,
The
and
from
A of free
Only
(1974)
steam,
"distance to zero
from far
representation
the
from
of the
an essential
the
the
critical
of to
Cv
between
their
and
analytic
the
region
for
400
-1 I
-
I 150
L___________________---_~
I 200
Density,
I I I I I I I
I 250
I 300
kg/m3
met
by et
with
practical
Levelt al.
(1983b)
of
the isobutane
partial
success.
analytic
are
from
points
the
surface and
(1983)
the
potential,
generated
Waxman
in
switching.
In constructing
both Fig. 10. A scaled equation has been fitted to the PVT data of isobutane in the range indicated by the heavy rectangle, including data points generated from a global surface valid everywhere except inside the dotted rectangle. In most of the range of overlap, Cp values derived from either surface agree to within 1%.
scaled
representing
scaled
U
recently
properties
____---____
all A,
values of
A simple approach
-
have
intermediate
Sengers
410
state,
properties
employed
420
f is
t!oolley
it is not
possible
-
of
where
,
poiLEY;
equation
and
heat
switch
origin
Although
three
430
of
ASc+(l-f)A
it.
first
specific
difficulty:
4401
the
to a scaled
a variety
A=f
analytical
were
elucidated
as
only
gradually
a classical
constructed
energy
valid
of joining
one.
in representing
energy
he noted
problem
Rowlinson
crossing
who
decays
a representation
be a difficult
(1983)
defined and
a satisfactory data
to
Helmholtz
a suitably
with
point.
difficulties
free
the
point
satisfied
Chapela
function"
by Woolley
He wrote
to obtain
IJ, and
They
critical
be
critical
emerging.
work
the
f is a function at
been
state.
not
the has
a "switch
problems.
unity
obviously
around
representations
propose
equation C" of
will
range
of
Gallagher
in a range
where
representations valid,
in the
fit.
were
included
In this
way,
a good
mesh
two
surfaces
was
of
the
31 In the supercritical
obtained. less than Some
1% in the range
problems
experimental The
remained,
thermodynamic
as a classical variables
surface
equation
that crosses
solution
BEHAVIOR
Phenomenology We begin are familiar
over
the phase
behaves
from
it.
surface
Ising-like the first
to this problem
would
lack of reliable
be to construct
can be achieved
behavior
a point
functions
(1983) constructed
correction
and
the
equation,
terms.
by Fox, to whose
of
a
to the van der Waals
Wegner
was devised
by having
nonanalytic
and Sengers
three
by
(Fig. 10).
near the critical
be appropriately
Ley-Koo
validity
factor.
Ising-like
This
such as CP differed
claim
boundary;
of crossover
that
from
properties
contributing
Recently,
incorporating
the reader
CRITICAL
away
variables.
correctly
approximate topic
near
to the problem
in the thermodynamic
the physical
while
however,
surface
derived
both representations
data was the principal
ideal solution
single
range,
where
A simpler
paper
on this
is referred. IN FLUID MIXTURES
and classical by showing
corresponding
a picture
to all engineers.
of phase
In
states behavior
of binary
Fig. 11, a P-x diagram shown
fluid mixtures
along
some isotherms
temperatures critical
P
second
first
lower
component.
of the Above
temperature
component,
curves
loops
the critical
Horizontal
tielines
coexisting
phases
connect
Fig. 12 we display
In
schematically
the classical
corresponding-states of the mixture (1890).
The plot along
pure fluid
treatment
by van der Waals
behavior
shows the
isotherms
in reduced
It is assumed at constant
coordinates.
composition
obeys
equation
The mixture,
separates
P-V
for a
that a mixture
the same reduced state.
to
point,
lies at the top of the
loop.
Fig. 11. P-x coexistence loops (-) at constant temperatures Tl--Tq. For temperatures between the critical temperatures of the two components, the loops have a critical point (0) at the top. The critical line (---) intersects the loops. A tieline is indicated.
that line.
and shrink
zero at the critical which
the
of the
the coexistence
are closed
intersect
is
at
than the
temperature
critical
that
of a fluid mixture
of
however,
into two phases
32 because
of material
before the
P/PC
x=x1
the
pure
of material in
’
=--,q
‘y’
\’
\J-“\ \/’
\\
\_
(1)
/4 \
-y,j
critical
point,
which
acceptable point
above
as
long
the
two-phase
region.
There
are
tie
in this
plot
because
phases
have
in general
the
for
composition.
obviously
the and
the
are
finite
of the
mixture
are
fluids.
I where
separates
"vv
"sv
“sv
%s
the
the
pseudocritical
the
point
properties not
in the
at
the
show
these
considerations from
One
of
of
is not
identified
found
stability,
course,
pure-fluid This
strong
are
corresponding
can,
mixture.
analoaous
one-component
&
but
than
Cpx
diverging
Mixtures
divergences,
diverge
heat
critical
these
counteroarts
for
the
Thus,
strongly
and
coefficient
point.
to their
that
KTx,
specific at
no
Classical
predicts
expansion
dPx
from
the
critical
position
is
with
the
critical
pure
fluid
considerations
mechanical
Det
as
point
that
compressibility
thus
properties
mixture phase
enters
lines
and
the the
mixture.
It is carefully first
mixture
is a pseudocritical
of the
Stability
the
of
isotherm
states. that
of
top
curve
rather
maintain
point
is
that
boundary
theory
Fig. 12. The mixture of composition x has the same reduced eouation of state as the pure fluid, but'separates at the curve of material instability (-----) rather than that of mechanical The pure-fluid instability (-). critical ooint (0). (1). Is a pseudocritical o>nt for-the mixture, for which (O), (2), is the real critical noint.
Note
critical
different
‘1’
of The
instability
12.
at the
coexistent
\\ \
-----
Fig.
curve
is reached.
shown
is not
\
fluid
curve
the
instability,
coexistence
explained
into
two
stability 2
0
in Rowlinson's
phases
because
book
(1982)
of mechanical
that
the
instability.
The
condition
is
>
(10)
I
indices
S, V denote
partial
derivatives
of the
energy
U with
respect
33 to entropy value
S or volume
0, from which
V. At the critical
it follows
also a P and CP) are strongly (a'P/aVZ)T=O
is needed
critical
isotherm.
written,
following
free energy AVV
Det I where
divergent.
10,
the determinant
The second
criticality
the stability
(.1982), in terms
reaches
the
so that KT (and, a fortiori,
to remain mechanically
For a binary mixture, Rowlinson
point,
(aP/aV)T=O,
for the fluid
A at constant
AVX
that
condition,
stable along
requirement
of the derivatives
the
may be
of the Helmholtz
temperature:
T=constant,
(11)
AVx Axx I it is to be remembered
everywhere,
except
From Eq. (11) and further criticality where
conditions
stability
derivatives,
because
laboratory.
Some notable
Observations
of strong
experiments,
anomaly since
anomalies
will,
plot of log I vs. log (T-Tc) yields
observed
it in the binary
point and Giglio dioxide
An interesting a chemical ionized
between
force
ionized
Thirdly, not diverge
although strongly,
aPx and Cpx diverge A fourth
case
(1973) found
fluid, develop
since
it
are usually in the
next.
in light-scattering I of scattered
point.
Charge
and
and Sengers
(1968)
near the consolute
it in the gas-liquid
mixture
of
point. at constant
An example
conservation
A
is steam
is by inducing being sliqhtly
and the chemical
on a path of a=O, so that
measures
light. A
line of slope yzl; White
the binary mixture
its components.
steam
observed
in pure C02. McIntyre
steam to remain
CPA, not Cpx!
Remarks
equilibrium
its properties by Gates et al.
is not a mixture.
the compressibility an exception
of a binary mixture,
is the case of critical
in general,
azeotropy
where
does KTx.
just as in the pure fluid.
in which
that of the density
a straight
near the plait
are those of the pure fluid--one (1982) notwithstanding,
be discussed
3 methylpentane-nitroethane
way to observe
at its critical
condition
liquid
and Vendramini
reaction
Thus
and along with
is not manipulated
to the intensity
this behavior
and propylene
however,
is directly
it is proportional
reported
(a2a/ax'lpT=0,
A=p2-~,, and x=x2.
strong divergences A
term.
that the
in fluid mixtures
of (ax/aA)pT
(1971)
is (aA/ax)pT=O,
These
is analytic
of the mixing
it can be derived
potentials,
the field variable
exceptions
Maccabee
carbon
mixture
of chemical
such as Cpa; apA, etc.
observed
The strong
free energy
(a~/aA)~~ is strongly divergent,
susceptibility
not directly
Helmholtz
considerations
of the binary
A equals the difference
the osmotic other
that the classical
at x=0 and x=1 in view of the properties
a strong
gradient
its local chemical
a strong density
anomaly
induced
potential
gradient
is directly
observed
by the field of gravity.
related
varies
linearly
to the diverging
with
in mixtures
is
A one-component height,
will
compressibility
KT;
34 this the
density key
liquid
gradient
to the mixture,
develops
with
an equally
ibility
quite
performed resulted
by
both strong
Straub's
KTb.
profiles
was
observed
Hocken-Moldover
in strong
chemical
et
to those
al.
density
(1983)
(1965)
mentioned varying
in mixtures in pure
gradients
the
C02.
Straub
linearly
Recent
and
with
and
N20
give
was
gas-
height,
diverging
model
He3-He4
(1965)
A binary
to the
of CO2
mixtures
(Fig.
and
earlier.
related
gradient,
for
x-
z.g
Schmidt
potentials
density
experiments
analogous
Chang
by
experiment
compress-
density
calculations
and
C02-C2H6
also
13).
*(lo-S)
.8
m4 0.0
E
.p
-.4
8
-.8
-1.6
F7'g. 13. Model calculatlgns of gravity effects in mixtures of 50, 72 and 84% . . being azeotropic. The CRH6 in CO2, within 5x10) from Tc, the second mixture are strong, several percent over a few mm height, just density gradients (The concentration gradients (-----) have a complex as in one-component fluid. After Chang et al. (1983). structure. The
fifth
extraction. maintains
the
concentration
behavior flui‘d.
case
where
Here,
the
solute's versus
as the curve
a strong
anomaly
becomes
presence
of the
chemical
potential
pressure,
near
the
of densi‘ty Yersus
solute
visible
in a second,
virtually
is that
constant.
critical
endpoint,
pressure
for
of
supercritical
generally The
shows
solid curve
the
a near-critical
phase
of
same one-component
35 Nonclassical It will
critical come
the classical behavior weak
theory
is taken
of fluid mixtures
with
pressure,
variables;
c is a field
to 1 as the mixture (1970).
is a dependent
variable
be y anomalies
earlier
just
model
concerns
by the same procedure,
the binary
variable
is a normalized
from pure component
predicted
as in the one-component
based on For the
gas-liquid
phase
5 as independent
activity
and runs from 0
shortly,
2.
See
the pressure
fluid model.)
(PI
the
fluids.
1 to pure component
to be described
by
if nonclassical
problem
for one-component
and third
which
anomalies
interesting
let us consider
(In the mixture
variable,
will
to find those
employed
temperature
varies
that the strong
The really
conceptualization,
transition
Griffiths
proceed
considerations,
sake of easier
to learn
into account. We will
anomalies.
geometrical
behavior
as no surprise
Fig. 14,
In
:w
“field”
5 “field” Fig. 14. Space of independent field variables for a binary gas-liquid mixtures. 5 is a function of the two chemical potentials. The vapor pressure curves of the two components are indicated at t,=O and c=l, respectively, while the critical line (----) connects the two critical points. In a plane c=constant the scaling behavior is that of the pure fluid; cf. Fig. 6 for the choice of scaling variables. we plot the space of independent curves
critical reason
variables,
at c=O and (;=l. The physical points.
The two-phase
as in Fig. lb, since
region
the field
with
critical
the two pure-fluid
line connects
has collapsed variables
to a surface
are equal
vapor
pressure
the two pure-fluid for the same
in coexisting
phases.
36 Critical-point
universality
demands
that
at constant
5 be that
of
scaling
constants.
Note
nonclassical
constant terms
field
of
the
approach tion
on
The
developed
the
u t,
one,
parallel
two
Derivatives
taken
that
is the
of ut,
or
just
such
predicted
by
is a third the
in the
case
line
and
behavior expect
to be
These all
surface
the
if there
Griffiths of
The
just in the
the
as
classical and
erature We been
by
PC,
and
C
of
the
several
bears on
nonclassical nonclassical
the
vapor-liquid
fluids.
by Wenzel
prediction
that
and
one
situations
azeotropy.
in pure
paper
generalized
are
show etc.,
as there
that
the
critical
in which
This
point
line was
in
densities the
same
unevent-
themselves.
Thus
mixtures.
just
to
along
manifold
in a three-component
Px1x2
relation
V
this
mixtures
two
direction,
those
a special
along
of finite,
to multi-component
weak
a
of constant
namely
surface PC,
it.
direction,
critical
by keeping
CVx,
and
path
in fluid
fluids,
to
constant,
taken
dimensional
critical
angle
as
the the
passes
coexistence coordinate
through
discussed
In
in one-
axes,
an extremum
in detail
by
(1970).
predicted
and
found
n-l
any
chosen,
direction,
second
(instead
Finally,
as
strong
surface
conspicuous
curve,
divergent
are
density
the
at
constant.
The one
fluid,
Tc,
KSx
kept
descrip-
fluid:
at an
Derivatives
parameters
readily
one
temperature
Wheeler
these
most
the
are
keeping
is obtained
along
such
Exceptional
critical
is critical
liquid-liquid
curve,
are
is only
if the
and
T,
in one-component the
uU,
a
in
nonclassical
nonclassical
is a strong
nondivergent.
fluids. or
instance,
Which
taken
other
of
is phrased
directions
strongly. by
surface.
direction
derivatives
there
component
$ and
weakly
the
The
r;, two
one-component
along
critical-line
considerations
cases,
for
the
or
that
of the
nonuniversal in terms
states
one-component
the
states).
available
in binaries
two
the
is phrased
surface
diverge
are
KTx,
the
and
It is obtained of the
also
of constant
coesistence
This
of
instance
corresponding not
that
direction
aPx,
derivatives as
second
mixture,
the
CPx,
mixtures.
constant, ful
with
direction
n-component
or
this one.
behavior
from
point.
coexistence
for
critical
corresponding Note
direction
the
fields,
classical
critical
special
weak
as
with
apart
universality
x.
in a plane
along
x is confluent
direction,
we
as
anomalous
fluid,
classical
variable,
intersects
in which
because,
line,
to the
that
pure
of a pseudocritical
in analogy
critical
direction
direction
density
not make use
does
is then
point
5, whereas
variable,
constant
that
the
the
mixture
anomalies effect type,
A dozen in this
fails
classical
is the
examples
volume.
to model curve
have
the
been
in binary
flattening
of
such
tlis work data
overshoots
near
the
observed?
mixtures,
flattened
shows the
both of the
of
curves
convincingly
top
experimental
the
coexistence
of the
can
coexistence
critical
temp-
degrees.
already
mentioned
observed
in fluid
that
the
mixtures
y-anomaly from
the
of
the
intensity
osmotic of
susceptibility
scattered
be
that
light;
has y-values
37 close to 514 have been reported ml'xtures, see, for instance, larger
than
behave
volume, like
observed of such
description,
The subtle
theory.
in a number import that
Of the weak anomalies unequivocally
The anomaly
is strikingly
flattening
studied.
I
I
point accord-
of the excess
volume
curve
cf. Scott's
to
has been
review,
but is not
sleepless.
,
only the last one has been seen
Fig. 15 displays measured
I
the specific
by Bloemen
to that of CV in argon
1
(a2HE/sx2)BT,
critical
according
triethylamine-water similar
enthalpy,
finite
in KTx, CZ,,~and Cpx
mixture
One is that the curvatures
they remain
keep engineers
in all mixtures
the liquPd-lfquid
while
critical
The fact that y is
zero at the mixture
of liquid-li'qufd mixtures, i‘t will
and in liquid-liquid (1978).
consequences.
approach
Ix-xc~'-',
by Scott
and of the excess
(a2yE/ax2)pT,
ing to the nonclassical classical
in gas-liquid
1 has some less-Mediate
of the excess which
both
the review
(Fig. 3).
1
heat of
et al.
(1981).
Fig. 15
I
I
(1) Triethylati-Water (2) Triethylati-\-Ethanol IXE =O.O7l (3)Tri&hylamine-Emoter-EthmolIXE =O.lOJ (Ll Triethyhmine-l-!euvyWater
I
cpx(~-!_)
:;
ill",
T PC)‘Fig. 15. The weak divergence of Cpx in triethylamine-water is analogous to that of C i‘n argon (Fig. 3). Addition of a small amount of a third component destroys 1 he divergence.- After Bloemen (1981). also which
shows how this anomaly
is quenched
is in this case the mole
For a vapor-liquid from the review
system
by Voronel
fraction
if another
density
of a third
component
the same quenching (1976).
phenomenon
The weak anomaly
is held constant added
to the mixture.
is displayed
of CV in ethane
in Fig. 16, is eliminated
38
22
26
30
34
38
42
46
50
54
58
T."C The weak diveraence Fig. 16. of a small amount of heptane. by the The not in
addition weak
been
of a small
anomalies
observed
KTx was
predicted
Nonclassical
fluids.
variables
and
relatively one-component in Table
The
the
easy
use
of
the
in the
cases
to Tc
component
and
are
the
proceeds
the
same
parametric there
that
were
it was
along
the
mole
fraction.
compressibility modeled,
not
have
the
increase
observable.
same
incompressible
binary,
lines
choice The
representation. is a one-to-one
of
binary
as
one-
liquid
correspondence
indicated
for
scaling is
between
the
schematically
Parametric
form
X
krBe
A
arE6e(l-e*)
P
principle at any
and
analytic
scaled
part
~.I
akr2-ap(e)
-p2 G
mixture
of
binary
AP
the
that
at constant the
-- appropriate
U
the
and
I.
PA
By
maintained
coefficient
so close
since
Analogy one
--
of mixtures tools
to model,
fluid
heptane,
by the addition (1976).
of mixtures
modeling
component
of
expansion
certainty
to occur
modeling
Nonclassical
amount
in the
with
of CV of ethane (1) is destroyed (2) -l%;(3) -3%. After Voronel
of
akr*-*[e*(l-8*)-p(e)] universality,
constant
pressure
background
are
the
representation
in Table
Only
the
non-universal
considered
to
be functions
P.
1 is valid
scale of
for
factors
pressure
the
a,
(Levelt
k
39 Sengers,
No systematic
1983c).
in liquid-liquid
mixtures
The modeling (1973)
of gas-liquid
for the mixture
and is illustrated fluid,
P=P*/T*
critical
form,
constants those
in terms
(1977)
(1983)
for the mixture this last sented
We refer
evidence
near the critical The tools mixture
near critical
for engineers.
locating
Dilute
shown
model
have
by Moldover
by Rainwater
by Chang
and Gallagher
explanation
and
et al.
(1983)
in Fig. 13 was taken
in nonazeotropic
lines
methods
for relatively
from
(1977)
of the model,
pre-
and for the
VLE data
and in azeotropic
are either
is desired
Secondly,
that
mixtures
models
subtle
many
will
models
line,
which
critical
techniques
and Wheeler
effects
detectable,
predicted
we believe
in those applications
particularly
for
Such
Andersen
of the nonclassical
be inevitable
near the critical
calculations
the existing
have been developed.
or not experimentally
models
of nonclassical do have certain
complicated
So far, no predictive
from the lattice Although
modeling
discussed
are rather
constants.
in nonclassical
may come
accurate
The procedures
the calculation.
the use of nonclassical accuracy
and SFG-C3HB,
by Moldover
First of all, these
have been developing.
in mixtures
factors.
in para-
COB-C2H4,
of the fit of near-critical
lines.
of adjustable
input to
critical
predictive (1979)
an
the
line.
a proliferation
line forms
effect
both
are thus available
behavior
drawbacks
of the excellence
in the pure
where
is described,
for the mixture
for a clear
with this model
before
serve as reduction
and C4H10-CBH,B,
to the paper
meeting
may
behavior
C02-CBHS
CH4-N2
the gravity
CO*-CBHG;
and Griffiths
to that
and 7=1/T*,
of the Griffiths-Leung
(1975)
for the mixtures
at the Asilomar
pictorial
in dilute
that
where
mixtures.
mixtures
A variety when
Variants
for the mixtures
paper.
can be obtained
with
are
et al.
by Leung
ut (Fig. 14). The nonuniversal u P' interpolated as functions of 5 between
of the variables
out by D'Arrigio
and Gallagher
a2=+*/T*
5, the thermodynamic
background
anomalies
the lines discussed
is, in analogy
The potential
of ~,=~,*/T*,
of the two pure components.
Moldover
first developed
of one of the two components
and analytic
been worked
was
of the thermodynamic
to date.
This was done along
in Fig. 14.
as a function
parameters
analysis
mixtures
3He-4He.
In the plane of constant metric
scaled
has been performed
of recent
a fluid mixture
for instance,
the poster
large and negative solubility volume,
is another some
partial
behavior
of these
results
have resulted
the critical
by Eckert
in supercritical
by invoking critical
experiments
is near
molar
et al.
volumes
extraction, remarkable
of classical
is a simple
point
in apparently
in the present of the solute.]
the topic effects. theory,
consequence
strange
behavior
of one of its component proceedings
The enhancement
of a number By means
we will
[see,
reporting
of papers
of the in this
of some pictures,
show that this
of the near-criticality
and
"remarkable"
of the host,.
40 In
Fig.
17a,
we
plot
the
volume
of
a binary
mixture
as
,-
a function
of composition
\
1
‘\
,’
\\A/’ X
0
1
Fig. 17. (a) The Vx diagram of a gas-liquid mixture at a temperature between the critical temperatures of the two components. At the critical point (e), the partial molar volumes are obtained by drawing the tangent to the coexistence curve () and intersecting it with the x=0 and x=1 axes. An isobar (---) is drawn. The excess volume VE for this isotherm-isobar is constructed and displayed separately, (b).It is large and negative because the mixture undergoes a phase transition along the isobar. at a temperature but
far
phases
below as
we draw the
soon
the
liquid
therefore, 17a,
tielines phase.
toward
(vapor)
since
sense.
should
appear
be strongly reported behavior,
isobar
both
We can (Fig.
negative
by the see
17b).
low-volume
side
Christensen
Schofield
It will emerge
of
on
the
are
Because of
group
et al.
of
the
the
for
the
the
the
in the the
dilute
The
mixtures
curve.
17a in
In
will, Fig.
at the
side.
Had
would
we
have
Griffiths-Wheeler
excess
separation, excess
two
Fig.
to zero,
situation
"densities"
into
In
region
(liquid)
analogous
phase
shrinks
two-phase
solvent,
predominately
coexistence
predict the
host
splits
solute
low-volume
how
the
is added.
tie-line
of the
an
range.
(1983).
of
system
component
enter
volume,
immediately
the
phases,
where
and
in part
second
point,
properties now
temperature a case,
coexisting
is drawn.
instead
such
of the
critical the
critical
In
amount
side
enthalpy
found,
the
solute.
connecting
be off
(1970)
above
the
The
large-volume the
of
as a small
a typical
plotted been
slightly
that
volume excess
enthalpies show
indeed
or enthalpy volumes
will
recently this
expected
Even more understand
striking
effects
this effect,
and v2 at the mixture will
obviously
obvious
A(x,V,T)
mixing
term
A,/v = A;Vx x + A;VT
(aT) *
= Aix + "
where
with
The partial behavior
v2
immediately
of v2 and the
of the Helmholtz
in which
expansion
It is readily
(11) are,
To
v,
volume
is not
of the divergence
point,
some care.
molar
of v,
expansion
volumes
found
to leading
free
of the
that the
order:
....
,
the subscripts
indicated, which
AVV
denote
is zero.
(11) equals
Here
finite.
Along
-RT P,T = __
that
, so
Thus,
strongly however,
v, now approaches
of a nonclassical
The
V,.
model.
are reported
approach
should
as was Strongly
by Eckert
Let us now speculate which
difference
with
line,
point
as x4,
their
between
be similar
about
AVV goes to zero
product
remaining
x and AT is asymptotically
v,
+
v,
+
_!$_
(13)
.
AVx approach
V,!
of v2 to infinity
of the partial noted earlier
molar
Along
the critical
is as
1~1-*'~,
while
to the
limit
volumes
by Wheeler
partial
et al. in this
the behavior
respect
we have
;
negative
at
the determinant
is approached,
Ax, diverges,
and v, does not the approach
is thus path-dependent,
dilution
the temperature On the critical
XAVx
v2 diverges
isotherm/isobar,
to the variable point,
that V2 + V, - s
X%X
respect
critical
line the relation
on this path,
with
to the pure-fluid
critical while
to x)
the critical
it follows
T-T,,
temperature.
As the pure-fluid
0.
(proportionally
differentiation
c refers
AT equals
critical
strongly
linear;
partial
and the superscript
to the pure-fluid
x=0
17a.
nature
in the determinant
quantities.
Aix + . . . .
AVx = xx
in Fig.
critical
molar
of the parti,al molar
from the classical
at the pure-fluid
occurring
by the partial
The limiting
The precise
figure.
is to be treated
derivatives
point
-m as x-4.
of v, can be derived
energy
A
critical
approach
from this
behavior
are displayed
see the construction
molar
(1972) on the basis
volumes
at infinite
volume.
of the partial
to that of the "partial
molar
molar
specific
compressibility."
heat, From
Eq. (12) it follows that along the critical line KTx, proportional to Avv-', -1 diverges as x , since AT is linear in x along this curve. According to classical theory,
therefore, a "partial molar -2 , a very strongly behave as x
compressibility,"
must
diverging
strong
divergence
the critical Wood
(1981).
point
has been noted of steam,
Although
in dilute
in recent
in their
salt
solutions
measurements
explanation
proportional
property.
The onset
to aKTx/ax, of this very
a fair distance
from
of Cpx by Smith-Magowan
on the basis
of a corresponding-
and
42 states this
argument
will
not
they cause
assumed them
that
trouble
diverges
CPx
as long
strongly
at the
as the
solution
critical
point
critical
is far
from
line,
its critical
point. In supercritical a situation that low
the
a combination
of
solvent
two
than
mixtures,
constants
and
is very
lack
nonclassical) classical recently
Treating
near
of
the
host
inconsistency
of
power.
we
have
phase,
because The
in the density
the
sharp is due
liquid being
critical
so
of
isothermally,
solvent
the
of
to
phase
a
point.
when
limit
that
point
of
is taken
the
of
are
the
by
pure
host
This
does,
mixture,
along
into the
1902).
of
state
Fig.
however,
critical
the nothing
will
effects
account,
12.
is modified
(to reflect
which
by
was
(1980),
(1901,
by a study
non-classical
taken
mixture
et al.
of
It
(preferably
dilute
Keesom
of
simple
line.
an approach
Hastings
equation
the
of
neglect
fluid
x-0
the
though
critical
Such
be grasped
isotherm). point
The pure
see
behavior
of adjustable
an accurate
x.
mixtures can
the
treat
small
authors,
means
critical
then
of
the
approach,
near
to give
and
as
critical
in the
the
host limit
to model
proliferation
classical
namely
of dilute
critical
the
The
present
classically.
those
pure
in the
is incorrect,
the
be used
is desired
course,
the
the
and
vicinity
while
the
solvent,
host.
soluble
of complication,
accuracy
accurately
of
dome
completely
mixture,
near
pure
solvent's
in principle,
treatment
idea
vicinity
of the
improve
when
states
by one
pure
can,
a middle
classical this
the
flatness
behave
to try
proposed
Unfortunately,
more
the
the
which,
is raised
being and
pressure
predictive
description
the
of
of the
pressure
solute
of
an additional
endpoint
point
phase,
drawbacks
fail
corresponding
following
in the
the
of
will
tempting
the
the
vapor
model
with
predictive,
critical
as
mixtures
Griffiths-Leung
dilute
in excess
at a critical
as
factors: in the
function
of dilute
The
to the
solubility,
increasing
Modeling
and
the
the
is present
critical
is close
of
near
solute
becomes
solubility,
sharply
the
mixture
enhancement
of the
extraction
where
to
still in the
will
lead
to
line.
Conclusions Nonclassical
behavior
critical-point equations. quite
using
for
and
such
are:
working the
pure
of no
as the
fluids
fluids
and
of
the
for
the
fluid
such
weak
as
the
to the
solvent. mixtures.
curve
an accurate
of
Others
are
and
region;
power
and
cycles;
Nonclassical In the
the
are
generation
supercritical are
KTx, quite
is required.
power
models
treatment
the canonical
near-critical
description
supercritical
of
by analytic
divergence
engineer.
coexistence
in the
is a consequence
described
when
in supercritical of
mixtures
be properly
concern
ignored
transfer
point
fluid
effects,
flatness be
and
cannot
irmnediate
cannot
custody
critical
and
nonclassical
and
isotherms,
Examples
near
Some
subtle
apparent, P-V
in fluids
fluctuations
extraction
available
of dilute
both
mixtures,
if
43 the pure host critical
is described
anomalies,
used to describe mixture
model
with
a classical
the mixture
will
become
sufficient
accuracy
corresponding-states
near the critical
to reflect argument
the nonclassical can no longer
be
line and the use of a nonclassical
unavoidable.
Acknowledgements We have Wielopolski, figures
profited
from the
and R. H. Wood.
from their work.
insights
of J. C. Wheeler,
A. V. Voronel
J. Kestin's
remarks
and J. Thoen
R. L. Scott, permitted
led to several
P.
us to use
improvements
in the
manuscript. REFERENCES Andersen, G.R. and Wheeler, J-C., 1979. J. Chem. Phys. 70: 1326 - 1336. and Van Dael, W., 1981. J. Chem. Phys., 75: 1488 - i495. Bloemen, E., Thoen, J., Buckingham, M.J. and Fairbank, W.M., 1961. In: C.J. Gorter (Editor), Progress in Low Temperature Physics. North-Holland Publ. Co., Amsterdam, 3: 80 - 111. J., 1983. Submitted Chang, R.F., Levelt Sengers, J.M.H., Doiron, T., and Jones, to J. Chem. Phys. Chapela, G.A. and Rowlinson, J.S., 1974. Trans. Farad. Sot. 70: 584 - 593. D'Arrigio, G., Mistura, L., and Tartaglia, P., 1975. Phys. Rev. A12: 2587 - 2593. Erokhin, N.G. and Kalyanov, B.I., 1979. High Temp. 17: 245 - 251. Erokhin, N.G. and Kalyanov, B.I., 1980. Thermal Engr. 27 (11): 634 - 636. Eubank, P.T., Hall, K.R. and Nehzat, M.S., 1979. In: J. Straub and K. Scheffler (Editors), Water and Steam. Their Properties and Current Industrial Applications, Pergamon, Oxford: 120 -127. Gates, J.A., Wood, R.H., and Quint, J.R., 1982. J. Phys. Chem. 86: 4948 - 4951. Giglio, M. and Vendramini, A., 1973. Optics Comm. 9: 80 - 83. Goodwin, R.D., 1969. J. Res. Natl. Bur. Stand. (U.S.) 73A: 585 - 591. Griffiths, R.B. and Wheeler, J.C., 1970. Phys. Rev. A2: 1047 - 1064. Hastings, J.R., Levelt Sengers, J.M.H., and Balfour, F.W., 1980. J. Chem. Thermo., 12: 1009 - 1045. Hocken, R.J. and Moldover, M-R., 1976. Phys. Rev. Letters 37: 29 - 32. Kamgar-Parsi, B., Levelt Sengers, J.M.H., and Sengers, J.V., 1983. J. Phys. Chem. Ref. Data, in press. Keenan, J.H., Keyes, F.G., Hill, P.G., and Moore, J.G., 1969. Steam Tables, John Wiley & Sons, Inc., New York. Keesom, W.H., 1901. Comm. Phys. Lab. Leiden 75: 1 - 18. Keesom, W.H., 1902. Coenn. Phys. Lab. Leiden 79: 1 - 11. Le Guillou, J.C. and Zinn-Justin, J., 1980. Phys. Rev. 821: 3976 - 3998. Leung, S.S. and Griffiths, R.B., 1973. Phys. Rev. A8: 2670 - 2683. Levelt Sengers, J.M.H., 1973. Physica 73: 73 - 106. Levelt Sengers, J.M.H., 1976. Physica 82A: 319 - 351. Levelt Sengers, J.M.H. and Sengers, J.V., 1981. In: H.J. Ravechi (Editor), Perspectives in Statistical Physics, North-Holland Publ. Co., Amsterdam, Ch. 14: 239 - 271. Levelt Sengers, J.M.H., Kamgar-Parsi, B., Balfour. F.W., and Sengers, J.V., 1983a. Phys. Chem. Ref. Data, 12:1-28. Levelt Sengers, J.M.H., Kamgar-Parsi, B., and Sengers, J.V., 1983b. J. Chem. Eng. Data, in press, July 1983. Levelt Sengers, J.M.H., 1983c. Pure & Appl. Chem. 55: 437 - 453. Ley-Koo, M. and Green, M.S., 1981. Phys. Rev. A23: 2650 - 2659. Ley-Koo, M. and Sengers, J.V., 1983. In preparation. McIntyre, D. and Sengers, J-V., 1968. In: H.N.V. Temperley, J.S. Rowlinson and G.S. Rushbrooke (Editors), Physics of Simple Liquids, North Holland Publ. Co., Amsterdam, Ch. II, 448 - 505.
44 Moldover, M.R. and Gallagher, J.S., 1977. In: T.S. Storvick and S-1. Sandler (Editors), Phase Equilibria and Fluid Properties in the Chemical Industry, ACS Symposium Series 6Q, Ch. 30, 498 - 509. Cambridge University Pip ard, A.E., 1957. Elements of Classical Thermodynamics, ! ress. Rainwater, 3.C. and Moldover, M.R., 1983. In: M.E. Paulaitis, J.M.L. Penninger, R-0. Gray, Jr., and P. Davidson (-Editors), Chemical Engineering at Supercritical Fluid Condi;tions, Ann Arbor Science, Ch. 10, 199 - 219. Rowlinson, 3-S. and Swi.nton, F.L., 1982. Liquids and Liquid Mixtures, Butterworth Scientific, London, U.K. Schmidt, E.W., 1965. In: M.S. Green and J.Y. Sengers (Editors), Critical Phenomena, Proceedings of a Conference, Washington, D.C., 1965, NBS Misc. Publ. 273, 13 - 2Q. 606 - 608. Schofield, P., 1969, Phys. Rev. Letters 22: Schofield, R.S., Post, M-E., McFall, T.A., Izatt, R.M., and Christensen, J.J., 1983. 3. Chem. Thermo. 15: 217 - 224. Scott, R.L., 1978. In: M.L. McGlashan (Editor), Chemical Thermodynamics, Vol. 2, 2, Specialist Periodical Report, Chem. Sot. London, Ch. 8, 238 - 274. .S:;S;bMayOwan, D. and Wood, R.H., 1981. 9. Chem. Thewno. 13, 1047 - 1073. 1965. Ph.D thesis, Munchen. Van de; Wails, J.D., 1890. Z. Physik. Chem. 5: 133 - 173. Verbeke, O.B., Jansoone, V., Gielen, R., and De Boelpaep, J., 1969. J. Phys. Chem. 73: 4076 - 4085. Verschaffelt, J.E., 1900. Proc. Sec. Sci. Kon. Akad. Wetensch. Amsterdam, 2: 588 - 592. Verschaffelt, J.E., 1900. Comm. Phys. Lab. Leiden 55: 1 - 9. Vicentini-Missoni, M., Levelt Sengers, J.M.H. and Green, M-S., 1969. J. Res. National Bureau of Standards 73A: 563 - 583. Voronel, A.V., 1976. In: C. Domb and M.S. Green (Editors), Critical Phenomena and Phase Transitions 5B: Ch. 5, 344 - 394. Waxman, M. and Gallagher, J.S., 1983. J. Chem. Eng. Data, 28:224-241. Wegner, F., 1972. Phys. Rev. B5: 4529 - 4536. Wheeler, J.C., 1972. Ber. Bunsenges. Phys. Chem. 76: 308 - 318. White, J.A. and Maccabee, B.S., 1971. Phys. Rev. Letters 26: 1468 - 1471. Wood, R.H. and Quint, J.R., 1982. J. Chem. Thermo. 14: 1069 - 1076. in press. Woolley, H.W., 1983. Int. J. Thermophysics,
Fluid Phase Equilibria, 14 (1983) lS-44 Elsevier Science Publishers B.V., Amsterdam-Printed
CRITICAL
BEHAVIOR
J. M. H. Levelt Thermophysics
in The Netherlands
IN FLUIDS AND FLUID MIXTURES
Sengers,
Division,
G. Morrison, National
and R. F. Chang
Bureau
of Standards,
Washington,
D.C. 20234
ABSTRACT The presence of large fluctuations near a critical point leads to thermodynamic anomalies not present in classical, i.e., analytic equations, such as, that of van der Claals. We introduce the concepts of universality, critical exponents, scaling laws, "field" and "density" variables, "strong" and "weak" directions. Experimental evidence for the presence of nonclassical critical behavior in fluids and fluid mixtures is presented. A scaled thermodynamic potential represents the thermodynamic data of steam, ethylene and isobutane accurately. It is valid up to 1.07 T,, and within ?30% from pc. Methods for joining it to an analytic equation are discussed. The generalization to a nonclassical description of fluid mixtures is described, and applications are given. The engineer may require the nonclassical description in custody transfer, design of supercritical power cycles and supercritical extraction. The classical approach is used here to explain peculiarities of dilute mixtures recently reported by several experimenters.
INTFODUCTION The modern years, amongst point
theory
of critical
has crystallized theoreticians
prize,
about
forms
systems.
a decade
ago,
a mathematical parameter,
of the large
compressibility.
Haals
equation
fluctuations,
for fluids they
are
consequences
of these
fluctuations
is that
interparticle fluids)
that
and
interactions;
into
meter.
Non-ionized
0378-3812/83/$03.00
ranges
no longer
phenomena
character
d of the system fluids
class,
and fluid
larger
on the precise
details
have a character
characterized
mixtures
these that are
than the in most
of the
of universality;
different by only
near normal
0 1983 Elsevier Science Publishers B.V.
ignore
anomalies
(as they are
and the dimensionality
because
of the critical
of space much
in the many
point
such as the van der
for magnets,
character
introduced the Nobel
of the fluctuations
those critical
are short-ranged
depend
granted
descriptions,
The striking
over
of the critical
approach
near a critical
theory
to deal with
one universality
the dimensionality
classical
the mean-field
critical
the nature
the effects
predominant
If the forces
is, they are of identical
be grouped
Since
fluctuations.
will
the past twenty has been reached
he was recently
for describing
become
inadequate
spacings.
regarding
and for which
they extend
the phenomena
molecular
which
during
consensus
The renormalization-group
basis
of the order
developed
that a broad
and exnerimentalists
in many different
by Wilson
behavior,
to the point
systems
that
can
two parameters,
n of its order critical
points
parabelong
20 in the
universality
houses
uniaxial
disorder
phase
detailed
and
systems,
paper
show
critical from
theoretical
one-component
to
fluid
component some
on
the
a recent
CRITICAL
The cal
Helmholtz
P*=P/Pc
reduced
pressure terms
of
of
dilute
related,
of
the
departures will how
critical
have
be the
anomalies
been
extended
classical
paper
least
the
("scaled")
the
mixtures, at
characteristic
occur,
anomalies
The
engineer.
pressure
van
density
reduced
der and
critical
and
quadratic
The linear
isochore. a
Pij
and
only
order,
the
shown
approach.
in one
will
and
close
an area
in part,
index
two-
with
in which
to
the
aT*=T*-1.
AP*, namely
reduced
there
interest
Eq.
(2)
the
scaled
(1)
density
absent
on
vapor
pressure
the
(1973), equation with
(Ao*)~
because
right-hand curve
of
con-
terms
have
Eq.
P,,*(T) and
the
(1)
rearrangement
of
state:
a scaling
is a function
temperature
the
the
side
x=(~T*)/(ap*)~ of
the
of
a slight of
T*=T/T,, of
value;
density-dependent
terms
the
and
to derivatives
alone
is an example by
reduced
are
classicritical
,
...
related
the
write
a critical-point
Sengers for
+
we may
for
at
c denotes
{1+41/P30)x)
if divided
the
potential
be expanded
Thus
lowest-order
by Levelt
= P30(AP*)3
variable,
p*=p/pc, constants,
the
chemical all
+ P30(P*_l)3
density
expression
the can
temperature.
density-independent
As
and
the
in the
"scaled"
difference
are
and
Waals,
pressure,
point;
= P*-Pd*(T*)
two)
with
critical
such This
FLUIDS
the of
the
AP*
than
that
the
(1) yields
a~*=~*-1
the
(T*-lli + Pll(P*-l)(T*-1)
Eq.
pressure
to
the
working
descriptions
a
of
"scalina".
demonstrated
accuracy,
contrasted
of the
interest,
energy,
as
is the
to
actual
scaled
and
behavior
of
of criticality;
critical
Here
concern
into
of
nature
be
yielded
behavior
departures
then
also order-
behavior free
retained_
represent,
these
which
temperature;
linear
ditions been
at
of
series
‘* = ’ + I ‘oi the
way
be explained
critical
such
in Taylor
where
The
It will
with
have
show
The
these
experimental
IN ONE-COMPONENT
critical
equations,
point
transformed
been
name
indeed
systems.
in which
have
to within
do
class
alloys
methods
by the
mixtures
which
A-B
thermodynamic
goes
Ising-like
model,
and
extraction.
BEHAVIOR
Classical
also
fluid
Ising
critical
examples.
surge
in supercritical
the
ranges
be addressed are
of
Practical
will
fluids
been
the
fluids.
will
remarks
has
of
mixtures
question
renormalization-group
for
and
describe,
of
The
and
predicted
concepts that
3-dimensional antiferromagnets,
description
fluids
theory,
in a number
equations
The
which
anomalies
the and
description
that
classical
shown
of
transitions.
accurate
Ising-like will
class
ferromagnets
of
x=*T*/(~p*)~.
.
(2)
law: only
the one
From
reduced (rather
Eq.
(2)
21 On the critical isotherm where
we derive the following asymptotic power laws. AT*=O and PgP c, we have: lAP*j=IP*-l/ = P30jA~I &, with 6=3
.
(3a)
On the critical isochore, where Ap*=O, we have (aP*/ap*),, = P,, IAT*I~,
with r=l
.
(3b)
This equation implies that the compressibility
KT, which is proportional to
(aP*/aP*)T, diverges as IAT*j-', which is a strong divergence.
The expansion
coefficient CXP and the specific heat at constant pressure Cp diverge strongly, like KT, as follows from considerations
of thermodynamic
stability [see, for
instance, Rowlinson's book (1982)]. Coexisting densities are obtained by setting the pressure equal to the vapor pressure for AT*
=
The term in curly brackets in Eq. (2) is to be equal to
It follows that
(P,,~P~~)~AT*I'/~,
with
@l/2
.
(3c)
Finally, the analyticity of the Helmholtz free energy implies that the second derivative CV, the specific heat at constant volume, is finite.
Thus, on the
critical isochore,
r
D) P “field”
P
field’
Y
, “density”
T “field”
Fig. 1. Pressure versus density isotherms (----_), the critical isotherm (---), the critical isochore (------), the critical point (0) and the coexistence curve ( -) in (a) P-P space and (b) P-T space. The paths along which the critical exponents a, 8, y and 6 are defined have been indicated.
22 C *
=
V
/AT*I-~
with
Equations
(3a-d)
the
indicated
paths
Nonclassical
each
the
in
Figs.
critical
phase
producing fluctuation, curve
is
tions. 1900’s
flatter
can than
Scientists that
exponents
and
approach
and their
classical
values
along
lb.
that
critical
conditions,
because
two
phases
no longer
such
fluid
la
substantial
When the
they
critical
behavior phases
become
them.
(3d)
define
When coexisting in
.
a=0
of
can
low
transform
given
by the
curves
have
density
in
free
each
theory, have
indeed
an approximately
which
fluctuations energy
other
Consequently,
classical (1900)
the cost
into
be distinguished.
as Verschaffelt
coexistence
the
in
by spontaneous the
coexistence
ignores
known
since
cubic
shape,
fluctuathe
early
as
ETHYLENE, y
-T
hi’.
1 INDICATES
I _
1
I _
2
T-T,
01
.0.5 MlLLlBA
I
I
I
5
10
20
PC
labeled 1,2,3,4;were measured within +l% of Fig. 2. Four isochores of ethylene, (1980). Isothermal pressure differences the critical density by Hastings et al. between isochores 1 and 3, 2 and 4, and 2 and 3, are proportional to KT-~ and are The slopes of the straight lines provide plotted on a double-logarithmic scale. estimates of the critical exponent y.
23
1
_ ,p-0.521g/cm3 I
Cal/molK
Levelt
Sengers
showed
(1973,
1976).
The flattening
of the critical
lead to departures
from the classical
in the other
critical
instead
of
the value which
Most
known
volume,
the most
in argon
of 1976.
thermodynamic zero weakly
speed
to
the speed
of sound,
equations
of state,
Whether I
I
I
140
150
160
Fig. 3. The specific heat at constant volume of argon diverges weakly at the critical point, according to Voronel (1976). density
and as much
of 2% from Tc and 20% steam
from pc.
in the 50-parameter
constrained
tend to overshoot by a few degrees
steam
1980)
even
the critical
good-quality
and specific
multiparameter Webb and
exceeding
1% in
heat CR .in the range
the representation
et al.
temper-
C for Tc near room
lead to errors
instance,
not
at the critical
Rubin may
by Keenan
depends
equations
like that of Benedict,
used
as
(1979,
to pay atten-
equations
[See, for
equation
in
in classical
anomalies
Classical
point
as 25% in compressibility
namely "dip"
experimentally,
needs
nonclassical
ature
temperature;
This
and Kalyanov
the engineer
specifically
the approach
such as van der b!aals's,
on the application.
T, K
see his
point,
not present
of
in Fig. 4.
tion to these
1
heat at
has a non-
in super-critical
and displayed
predicts
the anomaly
of sound will
observed
by Erokhin
to
1900's.
indication
by Voronel,
]aT*lo".
has been repeatedly
130
theory
direct
at the critical
for instance
equal
As a consequence,
proportionally
measured
being
free energy
et
exponent
the early
Fig. 3 displays
CV measured review
in Fig. 2 of near-
of CV, the specific
the Helmholtz
analyticity.
than
since
5/4
by Hastings
nonclassical
divergence
constant that
to 5, rather
a fact
remarkably,
a weak
about
is shown
as measured
values
y exceeds
The critical-isotherm
6 is close 3, again
y equals
the compressibility
ethylene
(1980).
temperature
Thus the
the exponent
1 substantially
displays
critical al.
exponents.
exponent That
1.
studies
of this curve
and the depression
compressibility
/
in her historic
(1969).]
of Co of
24
l 653.23 ~666.23 A 673.23 x 698.93
500-
450
K K K K
J
-
c E _ u”
400-
350 -
I 25
I
30020
I 1 30 35 Pressure, MPa
I
40
45
Fig. 4. The speed of sound of supercritical steam according to measurements by Erokhin shows a minimum related to the weak divergence of C The full curves are predicted values according to a scaled equation by Leve Y‘t Sengers et al. (1983a). Densities
and
Consider variables
are
etc.,
are
P,".
are
property
strong
energy
U as
extensive
different intensive;
and
and,
they a
Wheeler
(1957)
Properties a density boundary
= (-l/v)(av/aP),
lb).
density.
a field,
These
constant
density
slope
the
are
the
of
or ap
of
with
the
being
constant
that
of
density
T,
S/V,
P,
first
type
terminology
of
of
thermodynamics of critical 4 He, developed superfluid
that
both
properties with
vapor
gives
like
respect
boundary the
are
intersects
strongly,
nonclassical
phase
U/Ni.
anomby
(1961).
hand,
a density and
The
in the
These
.
as
properties
= (l/V)(aV/aT),
diverge
other
classical
isochore path
of
such
phases.
"field",
the
that
V, Nl...
conjugate
in a direction
the
derivatives
is confluent
a
S,
properties
in coexisting
Fairbanks
derivatives On
In both
critical
and
variables
Their
fashioned after
Buckingham
descriptions.
along
who
KT
(Fig.
its
specific
second
by
KS=C-l/V)(aV/aP)S
of
the
mixtures
to
of
identical
and
constant
entiation
are
(1970)
respect
anomalies
phases.
like
with
nonclassical
weak
in general,
"density",
in multicomponent
Pippard
and
a function
in coexisting
is called
Griffiths alies
fields;
the
the
CV=(aU/aT)V
to a field
(Fig.
lb),
pressure results
curve.
and or
at
a path the
of
phase
in classical
description,
finite
derivatives
of
limiting Differ-
in classical
25 theory major
but produces distinction
the weak
exponent,
however,
performed
(constant
along which
anomalies
to be made
between
in nonclassical
critical
does not only depend
density-weak),
the critical
point
is approached.
ity shows a r-divergence
along
the critical
divergence Since,
along
however,
character
the critical this
isobar
"exponent
of the divergence
Thus,
is the of a critical
compressibil-
(Fig. la) but only a y/ii&
(both classically
and nonclassically).
does not affect
or weak),
is
but also on the path
the isothermal
isochore
renormalization"
(strong
This
The value
on the way the differentiation
constant
;
field-strong
theory.
exponents.
we will
the essential
not belabor
this point
further. Scaling
Laws
By far the easiest with
their
way to introduce
classical
counterpart,
reduced
chemical
potential
reduced
pressure
difference.
behavior
but the chemical
equation
of state with
lApi*/ = where
Dlap*16
h(x),
the nonclassical
The two quantities
potential
nonclassical
scaling
values
of all power
laws
compressibility the exponents
constants
and h(x)=l+x,
by letting
the functional
Since
before.
and the specific a and T cannot
in an
(4) classically.
B and 6 assume
their
form of h(x) appropriately
law, Eq. (4), can thus be seen as a compact
introduced
6 by the following
variable
Thus we write
,
law is obtained
and by choosing
The scaling
(see below).
is to begin
for the
than for the
dependent
variables.
B(AT*)/IA~*I"~
laws
have the same asymptotic
is the appropriate
o and T as independent
x =
scaling
this equation
AU*=~*-U~*(T*), rather
difference
B and D are two substance-dependent
The nonclassical
We write
Eq. (2).
the anomalous
heat can be obtained Indeed,
be independent.
from
behavior
"packaging"
of the
(4), it follows
they are related
that
to R and
relations:
2-a = .5(6+1); y = 8(6-l),
(5)
so that only two of the four are yielded
accurate
will
therefore
will
assume
values
not consider
theoretical
a = 0.110
* 0.0045
0.325
+ 0.0015
6=
(The exponent empty
unless
property
al will
these
estimates
y = 6=
region
1.241 ? 0.0020 4.82
the equation
shortly.)
of state
than those
A, = 0.498 t
theory
systems.
parameters;
and Zinn Justin
; .
(derived)
function
of Ising-like
as fitting
of Le Guillou
be introduced
other
Renormalization-group
exponents
exponents
a form for the scaling
is required:
the one-phase
; ;
independent.
for the critical
rather
has We
we
(1980). 0.020
; (6)
The scaling h(x)
should
law, Eq. (5), is
is specified.
The following
have no nonanalyticities
at the critical
point.
In addition,
in it is
26 desirable
that
for
thermodynamic
other
have
relations
these
et al. have
integrable
been
proposed,
an
higher-order
up*
= krsa
et
thermodynamic
function
variable"
two
obey
Eubank
in the
variables,
of a "contour
or all
et al.
one-phase
overcame into
variables r, raised
some
can
have
been
which
and
region
the
(1969),
All
of
are
not
difficulties physical
properties
are
to an appropriate
variable"
and
to
scaling
et al.
(1979).
these
be obtained hard
of the
by Vicentini-Missoni
(1969),
(1969)
expressions
requirements
that
instance, al.
Schofield
parametric
The
state
nonanalyticities
form.
so-called
analytic
for
closed-form
These
of
Goodwin
of a "distance
and
so that
functions.
(1969),
transformed.
products
integrable
equations
in closed
introducing are
be
Nonanalytic
fulfill.
Verbeke
h(x)
by
variables
written
as
fractional
power,
e as follows:
AT* = r(l-b202) AU*
= arBde(l-e2),
etc.
(7)
In
Fig.
5 we
of constant
4
I
I
‘/ !
e=o J
0 on
the
vapor,
coexistence
constant
+1
are
optimum
form
for
First
data.
represent prefer
fluids
not
the
seminal
and
Moldover
(1976)
the
only
in a small
asymptotic
critical
point.
of
laws
region Levelt
of
region
for
10-S
it to
in AT*.
are
valid the
Sengers
several
be of
Thus,
Hocken
around
estimated
found
most
demonstrated
(1961)
this
between
Furthermore,
Sengers
and
Secondly,
a property
experiment
that
equations
symmetry
possess.
in
state--we
form.
perfect liquid,
do
at
fluid
these of
only
not yet
describing all,
of the
nonanaly-
centered
a canonical
and
zero
all
(7) are
an equation
imply
vapor
of
of
Since
equals point,
Eqs.
side
A contour
shown.
neatly
point.
-1 on
liquid
curve.
variable
ticities
they
on the
critical
a equals
isochore,
r is also
distance
contours
fl; specifically,
the
this
several
critical
the
at the
Fig. 5. Parametric distance (r) and contour (.a) variables in the density-temperature plane for one-component fluids. The fulldrawn curves are contours of constant 0, some of which have been labeled by the appropriate 0 value. One contour of constant r (-----) is also indicated.
show
the
the
and
size
fluids, order
in order
to
of
27 apply
the scaling
choice those
of scaling
ideas we will variables
corrections
need
to asymptotic
and the use of the Wegner
Proper
scaling.
expansion
will
fulfill
goals.
Scaling
variables
The canonical of the
and Wegner
independent
direction
expansion
form we have variables
is singled
out,
preferred p=P*/T*
is the potential
and 7=-1/T*.
that of the phase
P=P*/T*
as a function
In the n-7 plane, Only one
transition
itself
sequently,
(Fig. 6).
one scaling
Con-
variable,
is chosen along this %" "weak" direction. The strong variable, intersect
If
u is chosen to IJ' the special direction.
it is chosen
at an angle
the T=Tc axis,
(Fig. 6),
aUIIHnetry between liquid
ii (which
equation;
(Up= 0)
Wegner
Fig. 6. Choice of independent scaling variables for one-component fluids, ut in the weak direction and ulr in the strong direction, in the plane of independent variables ;, T.
P=P i
reg
PSC
=
t-3
+Psc I_
ko
l”t12-a
+ P,,(A~)(AT)
. &rectfon-
as proposed
by
(1972) and worked
for fluids
by Ley-Koo
Green (1981),
out
and
we write
+ . . .
90(Uu/1Ut/CE)
+
go, g, are universal
In parametric
representation,
term.
The value
ak,l~~l~-~+*l
functions
gl(Up/Iutl~d)
of the scaling
g,, and g, are simple
of the ut in the first
the leading
P
,
The functions
exponent
part,
the
analytic!),
_
= *in + P,,(T)
a
latter
is not
the first
to-scaling
i
a classical
for the
relation
Including
in 7 and
is not to be
with
and a scaled
of a
regular
part
identified
and
The
P consists
Preg.
P(G,i)
vapor
is introduced.
potential part,
to
Wegner
correction
of the gap exponent
+
A,
is
is A, listed
uU/lutlBs.
in e2. higher
(8)
.
variable
polynomials term
,..
The
than
in Eq. (6).
that of In
28 the
regular
while
part
P,,
Applications
of
Expansion
the
(1980)
et al.
(1983a)
et al.
(1983)
range
the
potential,
of
to
been
used the
to represent heavy
1
the
is represented
asymmetric
as a polynomial
term
in T,
in Preq.
expansion
represent
for
PO(T
multiplying
Wegner
(8) has
et al.
The
of
is a constant
the
water;
applicability
.on around in a regi' equation
for
of
state
thermodynamic
critical
surface
and
by Levelt
the
case
of
the
of ethylene;
Sengers
steam
point
of steam; et al.
by Hastings
by Levelt
(1983b)
is indicated
Sengers
by Kamgar-Parsi for
in Fig.
isobutane.
7.
In
I
I
690 Y # z d k!
660
P
660
670
650
-24
640
-22 t
1
I
I
200
I
I
I
300 DENSITY,
400
I
650
b’,$
I
I
660
670
TEMPERATURE
(0)
units, (T*-1)
-0.005 The
Wegner
of 0.1% sound
the
0.07
in pressure
are
range
expansion
fitted
I
690
, K
(b)
Fig. 7. Range of applicability of in steam, (a) in P-p and scaling, reduced
I
I
660
is roughly
and
fits
the
level
the
p*
0.7
or better.
on the
the Wegner expansion, (b) in P-T space.
PVT
same
1.3
data
all
fluids
one
correction
investigated,
to namely
.
(9)
of these
Derivatives of a few
for
with
fluids
such
percent
to within
as CP,
or better
Cv and (Figs.
their the
accuracy
speed
4, 8,
9).
of The
29
I
500_
0 22.5651 v 23.5360 A 24.5166
MPa MPa MPa
I
I Sirota’s temperature scale lowered
400 Y
2
2 .
300 -
0”
x
Density,
kg/m3
Fig. 8. Prediction of the specific heat Cp of steam by the scaled equation with one Wegner correction-to-scaling, compared with the CP data measured by Sirota. After Levelt Sengers et al. (1983a).
0 640
.’
660
I
660
Temper0ture.K
Temperature.K
Temperature. K
9. Prediction of the specific heat Cv of steam by the scaled equation with Fig. one Wegner correction term, compared with the Cy data measured by Amirkhanov. After Levelt Sengers et al. (1983a).
30 Wegner
expansion
quality
thus
thermodynamic
gives data
a quantitatively of
pure
correct
fluids
in the
representation
critical
of
high-
region.
Crossover The
engineer
in a limited and
scaled
have
some
ones
to
solutions
of
co2.
functions these
Recent f for
was
able
energy
the
of
C
V
proved
reported
Helmholtz
of
for
steam,
The
and
from
A of free
Only
(1974)
steam,
"distance to zero
from far
representation
the
from
of the
an essential
the
the
critical
of to
Cv
between
their
and
analytic
the
region
for
400
-1 I
-
I 150
L___________________---_~
I 200
Density,
I I I I I I I
I 250
I 300
kg/m3
met
by et
with
practical
Levelt al.
(1983b)
of
the isobutane
partial
success.
analytic
are
from
points
the
surface and
(1983)
the
potential,
generated
Waxman
in
switching.
In constructing
both Fig. 10. A scaled equation has been fitted to the PVT data of isobutane in the range indicated by the heavy rectangle, including data points generated from a global surface valid everywhere except inside the dotted rectangle. In most of the range of overlap, Cp values derived from either surface agree to within 1%.
scaled
representing
scaled
U
recently
properties
____---____
all A,
values of
A simple approach
-
have
intermediate
Sengers
410
state,
properties
employed
420
f is
t!oolley
it is not
possible
-
of
where
,
poiLEY;
equation
and
heat
switch
origin
Although
three
430
of
ASc+(l-f)A
it.
first
specific
difficulty:
4401
the
to a scaled
a variety
A=f
analytical
were
elucidated
as
only
gradually
a classical
constructed
energy
valid
of joining
one.
in representing
energy
he noted
problem
Rowlinson
crossing
who
decays
a representation
be a difficult
(1983)
defined and
a satisfactory data
to
Helmholtz
a suitably
with
point.
difficulties
free
the
point
satisfied
Chapela
function"
by Woolley
He wrote
to obtain
IJ, and
They
critical
be
critical
emerging.
work
the
f is a function at
been
state.
not
the has
a "switch
problems.
unity
obviously
around
representations
propose
equation C" of
will
range
of
Gallagher
in a range
where
representations valid,
in the
fit.
were
included
In this
way,
a good
mesh
two
surfaces
was
of
the
31 In the supercritical
obtained. less than Some
1% in the range
problems
experimental The
remained,
thermodynamic
as a classical variables
surface
equation
that crosses
solution
BEHAVIOR
Phenomenology We begin are familiar
over
the phase
behaves
from
it.
surface
Ising-like the first
to this problem
would
lack of reliable
be to construct
can be achieved
behavior
a point
functions
(1983) constructed
correction
and
the
equation,
terms.
by Fox, to whose
of
a
to the van der Waals
Wegner
was devised
by having
nonanalytic
and Sengers
three
by
(Fig. 10).
near the critical
be appropriately
Ley-Koo
validity
factor.
Ising-like
This
such as CP differed
claim
boundary;
of crossover
that
from
properties
contributing
Recently,
incorporating
the reader
CRITICAL
away
variables.
correctly
approximate topic
near
to the problem
in the thermodynamic
the physical
while
however,
surface
derived
both representations
data was the principal
ideal solution
single
range,
where
A simpler
paper
on this
is referred. IN FLUID MIXTURES
and classical by showing
corresponding
a picture
to all engineers.
of phase
In
states behavior
of binary
Fig. 11, a P-x diagram shown
fluid mixtures
along
some isotherms
temperatures critical
P
second
first
lower
component.
of the Above
temperature
component,
curves
loops
the critical
Horizontal
tielines
coexisting
phases
connect
Fig. 12 we display
In
schematically
the classical
corresponding-states of the mixture (1890).
The plot along
pure fluid
treatment
by van der Waals
behavior
shows the
isotherms
in reduced
It is assumed at constant
coordinates.
composition
obeys
equation
The mixture,
separates
P-V
for a
that a mixture
the same reduced state.
to
point,
lies at the top of the
loop.
Fig. 11. P-x coexistence loops (-) at constant temperatures Tl--Tq. For temperatures between the critical temperatures of the two components, the loops have a critical point (0) at the top. The critical line (---) intersects the loops. A tieline is indicated.
that line.
and shrink
zero at the critical which
the
of the
the coexistence
are closed
intersect
is
at
than the
temperature
critical
that
of a fluid mixture
of
however,
into two phases
32 because
of material
before the
P/PC
x=x1
the
pure
of material in
’
=--,q
‘y’
\’
\J-“\ \/’
\\
\_
(1)
/4 \
-y,j
critical
point,
which
acceptable point
above
as
long
the
two-phase
region.
There
are
tie
in this
plot
because
phases
have
in general
the
for
composition.
obviously
the and
the
are
finite
of the
mixture
are
fluids.
I where
separates
"vv
"sv
“sv
%s
the
the
pseudocritical
the
point
properties not
in the
at
the
show
these
considerations from
One
of
of
is not
identified
found
stability,
course,
pure-fluid This
strong
are
corresponding
can,
mixture.
analoaous
one-component
&
but
than
Cpx
diverging
Mixtures
divergences,
diverge
heat
critical
these
counteroarts
for
the
Thus,
strongly
and
coefficient
point.
to their
that
KTx,
specific at
no
Classical
predicts
expansion
dPx
from
the
critical
position
is
with
the
critical
pure
fluid
considerations
mechanical
Det
as
point
that
compressibility
thus
properties
mixture phase
enters
lines
and
the the
mixture.
It is carefully first
mixture
is a pseudocritical
of the
Stability
the
of
isotherm
states. that
of
top
curve
rather
maintain
point
is
that
boundary
theory
Fig. 12. The mixture of composition x has the same reduced eouation of state as the pure fluid, but'separates at the curve of material instability (-----) rather than that of mechanical The pure-fluid instability (-). critical ooint (0). (1). Is a pseudocritical o>nt for-the mixture, for which (O), (2), is the real critical noint.
Note
critical
different
‘1’
of The
instability
12.
at the
coexistent
\\ \
-----
Fig.
curve
is reached.
shown
is not
\
fluid
curve
the
instability,
coexistence
explained
into
two
stability 2
0
in Rowlinson's
phases
because
book
(1982)
of mechanical
that
the
instability.
The
condition
is
>
(10)
I
indices
S, V denote
partial
derivatives
of the
energy
U with
respect
33 to entropy value
S or volume
0, from which
V. At the critical
it follows
also a P and CP) are strongly (a'P/aVZ)T=O
is needed
critical
isotherm.
written,
following
free energy AVV
Det I where
divergent.
10,
the determinant
The second
criticality
the stability
(.1982), in terms
reaches
the
so that KT (and, a fortiori,
to remain mechanically
For a binary mixture, Rowlinson
point,
(aP/aV)T=O,
for the fluid
A at constant
AVX
that
condition,
stable along
requirement
of the derivatives
the
may be
of the Helmholtz
temperature:
T=constant,
(11)
AVx Axx I it is to be remembered
everywhere,
except
From Eq. (11) and further criticality where
conditions
stability
derivatives,
because
laboratory.
Some notable
Observations
of strong
experiments,
anomaly since
anomalies
will,
plot of log I vs. log (T-Tc) yields
observed
it in the binary
point and Giglio dioxide
An interesting a chemical ionized
between
force
ionized
Thirdly, not diverge
although strongly,
aPx and Cpx diverge A fourth
case
(1973) found
fluid, develop
since
it
are usually in the
next.
in light-scattering I of scattered
point.
Charge
and
and Sengers
(1968)
near the consolute
it in the gas-liquid
mixture
of
point. at constant
An example
conservation
A
is steam
is by inducing being sliqhtly
and the chemical
on a path of a=O, so that
measures
light. A
line of slope yzl; White
the binary mixture
its components.
steam
observed
in pure C02. McIntyre
steam to remain
CPA, not Cpx!
Remarks
equilibrium
its properties by Gates et al.
is not a mixture.
the compressibility an exception
of a binary mixture,
is the case of critical
in general,
azeotropy
where
does KTx.
just as in the pure fluid.
in which
that of the density
a straight
near the plait
are those of the pure fluid--one (1982) notwithstanding,
be discussed
3 methylpentane-nitroethane
way to observe
at its critical
condition
liquid
and Vendramini
reaction
Thus
and along with
is not manipulated
to the intensity
this behavior
and propylene
however,
is directly
it is proportional
reported
(a2a/ax'lpT=0,
A=p2-~,, and x=x2.
strong divergences A
term.
that the
in fluid mixtures
of (ax/aA)pT
(1971)
is (aA/ax)pT=O,
These
is analytic
of the mixing
it can be derived
potentials,
the field variable
exceptions
Maccabee
carbon
mixture
of chemical
such as Cpa; apA, etc.
observed
The strong
free energy
(a~/aA)~~ is strongly divergent,
susceptibility
not directly
Helmholtz
considerations
of the binary
A equals the difference
the osmotic other
that the classical
at x=0 and x=1 in view of the properties
a strong
gradient
its local chemical
a strong density
anomaly
induced
potential
gradient
is directly
observed
by the field of gravity.
related
varies
linearly
to the diverging
with
in mixtures
is
A one-component height,
will
compressibility
KT;
34 this the
density key
liquid
gradient
to the mixture,
develops
with
an equally
ibility
quite
performed resulted
by
both strong
Straub's
KTb.
profiles
was
observed
Hocken-Moldover
in strong
chemical
et
to those
al.
density
(1983)
(1965)
mentioned varying
in mixtures in pure
gradients
the
C02.
Straub
linearly
Recent
and
with
and
N20
give
was
gas-
height,
diverging
model
He3-He4
(1965)
A binary
to the
of CO2
mixtures
(Fig.
and
earlier.
related
gradient,
for
x-
z.g
Schmidt
potentials
density
experiments
analogous
Chang
by
experiment
compress-
density
calculations
and
C02-C2H6
also
13).
*(lo-S)
.8
m4 0.0
E
.p
-.4
8
-.8
-1.6
F7'g. 13. Model calculatlgns of gravity effects in mixtures of 50, 72 and 84% . . being azeotropic. The CRH6 in CO2, within 5x10) from Tc, the second mixture are strong, several percent over a few mm height, just density gradients (The concentration gradients (-----) have a complex as in one-component fluid. After Chang et al. (1983). structure. The
fifth
extraction. maintains
the
concentration
behavior flui‘d.
case
where
Here,
the
solute's versus
as the curve
a strong
anomaly
becomes
presence
of the
chemical
potential
pressure,
near
the
of densi‘ty Yersus
solute
visible
in a second,
virtually
is that
constant.
critical
endpoint,
pressure
for
of
supercritical
generally The
shows
solid curve
the
a near-critical
phase
of
same one-component
35 Nonclassical It will
critical come
the classical behavior weak
theory
is taken
of fluid mixtures
with
pressure,
variables;
c is a field
to 1 as the mixture (1970).
is a dependent
variable
be y anomalies
earlier
just
model
concerns
by the same procedure,
the binary
variable
is a normalized
from pure component
predicted
as in the one-component
based on For the
gas-liquid
phase
5 as independent
activity
and runs from 0
shortly,
2.
See
the pressure
fluid model.)
(PI
the
fluids.
1 to pure component
to be described
by
if nonclassical
problem
for one-component
and third
which
anomalies
interesting
let us consider
(In the mixture
variable,
will
to find those
employed
temperature
varies
that the strong
The really
conceptualization,
transition
Griffiths
proceed
considerations,
sake of easier
to learn
into account. We will
anomalies.
geometrical
behavior
as no surprise
Fig. 14,
In
:w
“field”
5 “field” Fig. 14. Space of independent field variables for a binary gas-liquid mixtures. 5 is a function of the two chemical potentials. The vapor pressure curves of the two components are indicated at t,=O and c=l, respectively, while the critical line (----) connects the two critical points. In a plane c=constant the scaling behavior is that of the pure fluid; cf. Fig. 6 for the choice of scaling variables. we plot the space of independent curves
critical reason
variables,
at c=O and (;=l. The physical points.
The two-phase
as in Fig. lb, since
region
the field
with
critical
the two pure-fluid
line connects
has collapsed variables
to a surface
are equal
vapor
pressure
the two pure-fluid for the same
in coexisting
phases.
36 Critical-point
universality
demands
that
at constant
5 be that
of
scaling
constants.
Note
nonclassical
constant terms
field
of
the
approach tion
on
The
developed
the
u t,
one,
parallel
two
Derivatives
taken
that
is the
of ut,
or
just
such
predicted
by
is a third the
in the
case
line
and
behavior expect
to be
These all
surface
the
if there
Griffiths of
The
just in the
the
as
classical and
erature We been
by
PC,
and
C
of
the
several
bears on
nonclassical nonclassical
the
vapor-liquid
fluids.
by Wenzel
prediction
that
and
one
situations
azeotropy.
in pure
paper
generalized
are
show etc.,
as there
that
the
critical
in which
This
point
line was
in
densities the
same
unevent-
themselves.
Thus
mixtures.
just
to
along
manifold
in a three-component
Px1x2
relation
V
this
mixtures
two
direction,
those
a special
along
of finite,
to multi-component
weak
a
of constant
namely
surface PC,
it.
direction,
critical
by keeping
CVx,
and
path
in fluid
fluids,
to
constant,
taken
dimensional
critical
angle
as
the the
passes
coexistence coordinate
through
discussed
In
in one-
axes,
an extremum
in detail
by
(1970).
predicted
and
found
n-l
any
chosen,
direction,
second
(instead
Finally,
as
strong
surface
conspicuous
curve,
divergent
are
density
the
at
constant.
The one
fluid,
Tc,
KSx
kept
descrip-
fluid:
at an
Derivatives
parameters
readily
one
temperature
Wheeler
these
most
the
are
keeping
is obtained
along
such
Exceptional
critical
is critical
liquid-liquid
curve,
are
is only
if the
and
T,
in one-component the
uU,
a
in
nonclassical
nonclassical
is a strong
nondivergent.
fluids. or
instance,
Which
taken
other
of
is phrased
directions
strongly. by
surface.
direction
derivatives
there
component
$ and
weakly
the
The
r;, two
one-component
along
critical-line
considerations
cases,
for
the
or
that
of the
nonuniversal in terms
states
one-component
the
states).
available
in binaries
two
the
is phrased
surface
diverge
are
KTx,
the
and
It is obtained of the
also
of constant
coesistence
This
of
instance
corresponding not
that
direction
aPx,
derivatives as
second
mixture,
the
CPx,
mixtures.
constant, ful
with
direction
n-component
or
this one.
behavior
from
point.
coexistence
for
critical
corresponding Note
direction
the
fields,
classical
critical
special
weak
as
with
apart
universality
x.
in a plane
along
x is confluent
direction,
we
as
anomalous
fluid,
classical
variable,
intersects
in which
because,
line,
to the
that
pure
of a pseudocritical
in analogy
critical
direction
direction
density
not make use
does
is then
point
5, whereas
variable,
constant
that
the
the
mixture
anomalies effect type,
A dozen in this
fails
classical
is the
examples
volume.
to model curve
have
the
been
in binary
flattening
of
such
tlis work data
overshoots
near
the
observed?
mixtures,
flattened
shows the
both of the
of
curves
convincingly
top
experimental
the
coexistence
of the
can
coexistence
critical
temp-
degrees.
already
mentioned
observed
in fluid
that
the
mixtures
y-anomaly from
the
of
the
intensity
osmotic of
susceptibility
scattered
be
that
light;
has y-values
37 close to 514 have been reported ml'xtures, see, for instance, larger
than
behave
volume, like
observed of such
description,
The subtle
theory.
in a number import that
Of the weak anomalies unequivocally
The anomaly
is strikingly
flattening
studied.
I
I
point accord-
of the excess
volume
curve
cf. Scott's
to
has been
review,
but is not
sleepless.
,
only the last one has been seen
Fig. 15 displays measured
I
the specific
by Bloemen
to that of CV in argon
1
(a2HE/sx2)BT,
critical
according
triethylamine-water similar
enthalpy,
finite
in KTx, CZ,,~and Cpx
mixture
One is that the curvatures
they remain
keep engineers
in all mixtures
the liquPd-lfquid
while
critical
The fact that y is
zero at the mixture
of liquid-li'qufd mixtures, i‘t will
and in liquid-liquid (1978).
consequences.
approach
Ix-xc~'-',
by Scott
and of the excess
(a2yE/ax2)pT,
ing to the nonclassical classical
in gas-liquid
1 has some less-Mediate
of the excess which
both
the review
(Fig. 3).
1
heat of
et al.
(1981).
Fig. 15
I
I
(1) Triethylati-Water (2) Triethylati-\-Ethanol IXE =O.O7l (3)Tri&hylamine-Emoter-EthmolIXE =O.lOJ (Ll Triethyhmine-l-!euvyWater
I
cpx(~-!_)
:;
ill",
T PC)‘Fig. 15. The weak divergence of Cpx in triethylamine-water is analogous to that of C i‘n argon (Fig. 3). Addition of a small amount of a third component destroys 1 he divergence.- After Bloemen (1981). also which
shows how this anomaly
is quenched
is in this case the mole
For a vapor-liquid from the review
system
by Voronel
fraction
if another
density
of a third
component
the same quenching (1976).
phenomenon
The weak anomaly
is held constant added
to the mixture.
is displayed
of CV in ethane
in Fig. 16, is eliminated
38
22
26
30
34
38
42
46
50
54
58
T."C The weak diveraence Fig. 16. of a small amount of heptane. by the The not in
addition weak
been
of a small
anomalies
observed
KTx was
predicted
Nonclassical
fluids.
variables
and
relatively one-component in Table
The
the
easy
use
of
the
in the
cases
to Tc
component
and
are
the
proceeds
the
same
parametric there
that
were
it was
along
the
mole
fraction.
compressibility modeled,
not
have
the
increase
observable.
same
incompressible
binary,
lines
choice The
representation. is a one-to-one
of
binary
as
one-
liquid
correspondence
indicated
for
scaling is
between
the
schematically
Parametric
form
X
krBe
A
arE6e(l-e*)
P
principle at any
and
analytic
scaled
part
~.I
akr2-ap(e)
-p2 G
mixture
of
binary
AP
the
that
at constant the
-- appropriate
U
the
and
I.
PA
By
maintained
coefficient
so close
since
Analogy one
--
of mixtures tools
to model,
fluid
heptane,
by the addition (1976).
of mixtures
modeling
component
of
expansion
certainty
to occur
modeling
Nonclassical
amount
in the
with
of CV of ethane (1) is destroyed (2) -l%;(3) -3%. After Voronel
of
akr*-*[e*(l-8*)-p(e)] universality,
constant
pressure
background
are
the
representation
in Table
Only
the
non-universal
considered
to
be functions
P.
1 is valid
scale of
for
factors
pressure
the
a,
(Levelt
k
39 Sengers,
No systematic
1983c).
in liquid-liquid
mixtures
The modeling (1973)
of gas-liquid
for the mixture
and is illustrated fluid,
P=P*/T*
critical
form,
constants those
in terms
(1977)
(1983)
for the mixture this last sented
We refer
evidence
near the critical The tools mixture
near critical
for engineers.
locating
Dilute
shown
model
have
by Moldover
by Rainwater
by Chang
and Gallagher
explanation
and
et al.
(1983)
in Fig. 13 was taken
in nonazeotropic
lines
methods
for relatively
from
(1977)
of the model,
pre-
and for the
VLE data
and in azeotropic
are either
is desired
Secondly,
that
mixtures
models
subtle
many
will
models
line,
which
critical
techniques
and Wheeler
effects
detectable,
predicted
we believe
in those applications
particularly
for
Such
Andersen
of the nonclassical
be inevitable
near the critical
calculations
the existing
have been developed.
or not experimentally
models
of nonclassical do have certain
complicated
So far, no predictive
from the lattice Although
modeling
discussed
are rather
constants.
in nonclassical
may come
accurate
The procedures
the calculation.
the use of nonclassical accuracy
and SFG-C3HB,
by Moldover
First of all, these
have been developing.
in mixtures
factors.
in para-
COB-C2H4,
of the fit of near-critical
lines.
of adjustable
input to
critical
predictive (1979)
an
the
line.
a proliferation
line forms
effect
both
are thus available
behavior
drawbacks
of the excellence
in the pure
where
is described,
for the mixture
for a clear
with this model
before
serve as reduction
and C4H10-CBH,B,
to the paper
meeting
may
behavior
C02-CBHS
CH4-N2
the gravity
CO*-CBHG;
and Griffiths
to that
and 7=1/T*,
of the Griffiths-Leung
(1975)
for the mixtures
at the Asilomar
pictorial
in dilute
that
where
mixtures.
mixtures
A variety when
Variants
for the mixtures
paper.
can be obtained
with
are
et al.
by Leung
ut (Fig. 14). The nonuniversal u P' interpolated as functions of 5 between
of the variables
out by D'Arrigio
and Gallagher
a2=+*/T*
5, the thermodynamic
background
anomalies
the lines discussed
is, in analogy
The potential
of ~,=~,*/T*,
of the two pure components.
Moldover
first developed
of one of the two components
and analytic
been worked
was
of the thermodynamic
to date.
This was done along
in Fig. 14.
as a function
parameters
analysis
mixtures
3He-4He.
In the plane of constant metric
scaled
has been performed
of recent
a fluid mixture
for instance,
the poster
large and negative solubility volume,
is another some
partial
behavior
of these
results
have resulted
the critical
by Eckert
in supercritical
by invoking critical
experiments
is near
molar
et al.
volumes
extraction, remarkable
of classical
is a simple
point
in apparently
in the present of the solute.]
the topic effects. theory,
consequence
strange
behavior
of one of its component proceedings
The enhancement
of a number By means
we will
[see,
reporting
of papers
of the in this
of some pictures,
show that this
of the near-criticality
and
"remarkable"
of the host,.
40 In
Fig.
17a,
we
plot
the
volume
of
a binary
mixture
as
,-
a function
of composition
\
1
‘\
,’
\\A/’ X
0
1
Fig. 17. (a) The Vx diagram of a gas-liquid mixture at a temperature between the critical temperatures of the two components. At the critical point (e), the partial molar volumes are obtained by drawing the tangent to the coexistence curve () and intersecting it with the x=0 and x=1 axes. An isobar (---) is drawn. The excess volume VE for this isotherm-isobar is constructed and displayed separately, (b).It is large and negative because the mixture undergoes a phase transition along the isobar. at a temperature but
far
phases
below as
we draw the
soon
the
liquid
therefore, 17a,
tielines phase.
toward
(vapor)
since
sense.
should
appear
be strongly reported behavior,
isobar
both
We can (Fig.
negative
by the see
17b).
low-volume
side
Christensen
Schofield
It will emerge
of
on
the
are
Because of
group
et al.
of
the
the
for
the
the
the
in the the
dilute
The
mixtures
curve.
17a in
In
will, Fig.
at the
side.
Had
would
we
have
Griffiths-Wheeler
excess
separation, excess
two
Fig.
to zero,
situation
"densities"
into
In
region
(liquid)
analogous
phase
shrinks
two-phase
solvent,
predominately
coexistence
predict the
host
splits
solute
low-volume
how
the
is added.
tie-line
of the
an
range.
(1983).
of
system
component
enter
volume,
immediately
the
phases,
where
and
in part
second
point,
properties now
temperature a case,
coexisting
is drawn.
instead
such
of the
critical the
critical
In
amount
side
enthalpy
found,
the
solute.
connecting
be off
(1970)
above
the
The
large-volume the
of
as a small
a typical
plotted been
slightly
that
volume excess
enthalpies show
indeed
or enthalpy volumes
will
recently this
expected
Even more understand
striking
effects
this effect,
and v2 at the mixture will
obviously
obvious
A(x,V,T)
mixing
term
A,/v = A;Vx x + A;VT
(aT) *
= Aix + "
where
with
The partial behavior
v2
immediately
of v2 and the
of the Helmholtz
in which
expansion
It is readily
(11) are,
To
v,
volume
is not
of the divergence
point,
some care.
molar
of v,
expansion
volumes
found
to leading
free
of the
that the
order:
....
,
the subscripts
indicated, which
AVV
denote
is zero.
(11) equals
Here
finite.
Along
-RT P,T = __
that
, so
Thus,
strongly however,
v, now approaches
of a nonclassical
The
V,.
model.
are reported
approach
should
as was Strongly
by Eckert
Let us now speculate which
difference
with
line,
point
as x4,
their
between
be similar
about
AVV goes to zero
product
remaining
x and AT is asymptotically
v,
+
v,
+
_!$_
(13)
.
AVx approach
V,!
of v2 to infinity
of the partial noted earlier
molar
Along
the critical
is as
1~1-*'~,
while
to the
limit
volumes
by Wheeler
partial
et al. in this
the behavior
respect
we have
;
negative
at
the determinant
is approached,
Ax, diverges,
and v, does not the approach
is thus path-dependent,
dilution
the temperature On the critical
XAVx
v2 diverges
isotherm/isobar,
to the variable point,
that V2 + V, - s
X%X
respect
critical
line the relation
on this path,
with
to the pure-fluid
critical while
to x)
the critical
it follows
T-T,,
temperature.
As the pure-fluid
0.
(proportionally
differentiation
c refers
AT equals
critical
strongly
linear;
partial
and the superscript
to the pure-fluid
x=0
17a.
nature
in the determinant
quantities.
Aix + . . . .
AVx = xx
in Fig.
critical
molar
of the parti,al molar
from the classical
at the pure-fluid
occurring
by the partial
The limiting
The precise
figure.
is to be treated
derivatives
point
-m as x-4.
of v, can be derived
energy
A
critical
approach
from this
behavior
are displayed
see the construction
molar
(1972) on the basis
volumes
at infinite
volume.
of the partial
to that of the "partial
molar
molar
specific
compressibility."
heat, From
Eq. (12) it follows that along the critical line KTx, proportional to Avv-', -1 diverges as x , since AT is linear in x along this curve. According to classical theory,
therefore, a "partial molar -2 , a very strongly behave as x
compressibility,"
must
diverging
strong
divergence
the critical Wood
(1981).
point
has been noted of steam,
Although
in dilute
in recent
in their
salt
solutions
measurements
explanation
proportional
property.
The onset
to aKTx/ax, of this very
a fair distance
from
of Cpx by Smith-Magowan
on the basis
of a corresponding-
and
42 states this
argument
will
not
they cause
assumed them
that
trouble
diverges
CPx
as long
strongly
at the
as the
solution
critical
point
critical
is far
from
line,
its critical
point. In supercritical a situation that low
the
a combination
of
solvent
two
than
mixtures,
constants
and
is very
lack
nonclassical) classical recently
Treating
near
of
the
host
inconsistency
of
power.
we
have
phase,
because The
in the density
the
sharp is due
liquid being
critical
so
of
isothermally,
solvent
the
of
to
phase
a
point.
when
limit
that
point
of
is taken
the
of
are
the
by
pure
host
This
does,
mixture,
along
into the
1902).
of
state
Fig.
however,
critical
the nothing
will
effects
account,
12.
is modified
(to reflect
which
by
was
(1980),
(1901,
by a study
non-classical
taken
mixture
et al.
of
It
(preferably
dilute
Keesom
of
simple
line.
an approach
Hastings
equation
the
of
neglect
fluid
x-0
the
though
critical
Such
be grasped
isotherm). point
The pure
see
behavior
of adjustable
an accurate
x.
mixtures can
the
treat
small
authors,
means
critical
then
of
the
approach,
near
to give
and
as
critical
in the
the
host limit
to model
proliferation
classical
namely
of dilute
critical
the
The
present
classically.
those
pure
in the
is incorrect,
the
be used
is desired
course,
the
the
and
vicinity
while
the
solvent,
host.
soluble
of complication,
accuracy
accurately
of
dome
completely
mixture,
near
pure
solvent's
in principle,
treatment
idea
vicinity
of the
improve
when
states
by one
pure
can,
a middle
classical this
the
flatness
behave
to try
proposed
Unfortunately,
more
the
the
which,
is raised
being and
pressure
predictive
description
the
of
of the
pressure
solute
of
an additional
endpoint
point
phase,
drawbacks
fail
corresponding
following
in the
the
of
will
tempting
the
the
vapor
model
with
predictive,
critical
as
mixtures
Griffiths-Leung
dilute
in excess
at a critical
as
factors: in the
function
of dilute
The
to the
solubility,
increasing
Modeling
and
the
the
is present
critical
is close
of
near
solute
becomes
solubility,
sharply
the
mixture
enhancement
of the
extraction
where
to
still in the
will
lead
to
line.
Conclusions Nonclassical
behavior
critical-point equations. quite
using
for
and
such
are:
working the
pure
of no
as the
fluids
fluids
and
of
the
for
the
fluid
such
weak
as
the
to the
solvent. mixtures.
curve
an accurate
of
Others
are
and
region;
power
and
cycles;
Nonclassical In the
the
are
generation
supercritical are
KTx, quite
is required.
power
models
treatment
the canonical
near-critical
description
supercritical
of
by analytic
divergence
engineer.
coexistence
in the
is a consequence
described
when
in supercritical of
mixtures
be properly
concern
ignored
transfer
point
fluid
effects,
flatness be
and
cannot
irmnediate
cannot
custody
critical
and
nonclassical
and
isotherms,
Examples
near
Some
subtle
apparent, P-V
in fluids
fluctuations
extraction
available
of dilute
both
mixtures,
if
43 the pure host critical
is described
anomalies,
used to describe mixture
model
with
a classical
the mixture
will
become
sufficient
accuracy
corresponding-states
near the critical
to reflect argument
the nonclassical can no longer
be
line and the use of a nonclassical
unavoidable.
Acknowledgements We have Wielopolski, figures
profited
from the
and R. H. Wood.
from their work.
insights
of J. C. Wheeler,
A. V. Voronel
J. Kestin's
remarks
and J. Thoen
R. L. Scott, permitted
led to several
P.
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improvements
in the
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