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Dielectric relaxation of some binary liquid mixtures containing polyethyleneglycol as one component
JournalofMokcularLiquida.4D (19Bl)lOs-118 El&&r SciencePublisheraB.V.,~terdam
DIELECTRIC
105
RELAXATION
MIXTURES
OF SOME
CONTAINING
Institut
22
M. Stockhausen
fifr Physikalische
January
The permittivity 30
MHz
and
(PEGDM); ethanol, from
an
mixture
GE2:
PEG
200
contributions
FZG
with
or water.
400
(Germany)
with
The
2
0)
toluene
description
or PEG
4CO dimethylether
to
ethyleneglycol,
of the dielectric
superposition
(PEG-PEGDM)
(PEG-H
has been measured at 20 OC between
ethyleneglycolmonomethylether,
unperturbed
components
MCmster,
1991)
72
apparently
and G_ SchiItz
Chemie der Universitat
of the following mixtures
methanol
AS
COJMPONIZNT
Miinster
LIQUID
POL YETEYLENEGLYCOL
ONE E. Wessling,
BINARY
of
spectra
contributions
the occurance
ranges
from
of strong
both
additional
which are ascribable to heteroassociation.
Introduction Chain molecules, dielectric moments (PEG),
even those with only terminal dipole moments,
relaxation are
behaviour
distributed
H(OCH2CH2)pOH.
temperature,
are widely
0167-7322/91/$03.50
8
exhibit
a non-Debye
in the liquid state [x]. All the more this is the case if
along
the
chain
backbone,
These substances, applied
not
least
as
with
which for p s
because
of their
1991 -ElfmvierSciencePubliehemB.V.
polyethyleneglycols
10 are liquids at room water
solubility.
Allrights~rved
The
dynamic
dielectric
aqueous
ones
information mixture
properties
systems
may
hydrogen
The absorption be described
by
of
segmental
continuous
relaxation
components. and
noticed
[lo])
motions
frequency
opposite
time
dietherated
concerning region
short)
from
of the
with increasing
This
properties
may
systems.
solute
and
meaningful those
information previous
studies of in
terminal
be
revealed
of PEGs
and
of
solvent
concerning
studies mostly
substances
and
hydroq
coils,
probably
groups.
A
relaxation
particularly
(e.g.
region is mainly
within the flexible
PEG
the
due to
while the
inter-
peculiarity
and
already
time (which anyway
as viscosity
is
varies in the
increasing
weight
interpretation
of the
itself but on the mutual
in the
dynamic
soIvents,
which
dielectric
in particular
cannot
assuming
that
such
therefore
in particular
worthwhile
to
the variation
laid stress on the variation
a
interaction
properties water,
unambiguously
at all. In order to attain a better understanding seems
of discrete
process.
contributions,
it
a sum
related
absorption
motion
chain length,
in polar
spectrum
It CZLIIeither
it has been inferred from comparative
PEGS
the
or by
is not aimed at a more thorough
of the polymer
absorption
systems
from
interactions,
but unstructured.
decrease is likely to result from the relatively
possibly
Solutions
unstructured
Apart
chain, dielectric
distributions
the ether oxygens
arises
present communication
which
of
is broadened
Qualitatively
of the chain ether group relaxation
dielectric
in particnlar
years
of intermolecular
that the higher frequency
association
sense.
solutions,
many
of the PEG
in early work is the decrease of the effective
surprisingly
The
for
to the knowledge
of pure PEGs
mono-
intramolecular
and dynamics
contribute
and of PEG
attention
spectrum
polypropyleneglycoi
lower
attracted
[2-5]
bonding effecta-
type spectral
studies
have
[3,5-Q],
on the conformation
particular
Debye
of pure PEGS
be
of
show
of the dielectric
of the
of the PEG
more
mixture
mixture again
resolved
subdivision
gather
effects
an into
might
be
behaviour
experimental partner,
chain length.
while
107
Here
we report
relative
molar
nonpolar with
on PEG
mixture
B~~IIM
using
mass of 400 or 200. They may be arranged
solvent and with a dietherated
a fkw protic liquids
covering
(a)
some results
including
the whole mixture
derivative
PEGB
in two groups:
as second mixture
water_ The following
400 -
toluene
PEG
400 -
polyethyleueglycol4OO-dimethylether
a mean
(a) with a
component,
(b)
systems have been studied
range (except for the first mentioned
PEG
with
example) :
(PEGDM),
H3C(OCH2CH2)pOCH3 (b)
PEG
200 -
ethyleneglycolmonomethylether
PEG
200 -
ethyleneglycol
PEG
200 -
ethanol (EtOH)
PEG
200 -
methanol
PEG
200 -
H20_
The complex range
between
experimental The
30 MHz uncertainty
chemicals
further
The
permittivity
were
(EG),
(EGM),
H3COCsCH2OH
HOCH2C%0H
(MeOH)
of the liquids and 72 GHz
was measured
employing
at 12 spot frequencies
different
experimental
in the
setups. The
is a few percent. All measure ments are at 20 OC. from
Aldrich,
Fluka
aud
Merck.
They
were
used
without
purification.
permittivity
the Cole-Cole
data
were tentatively
or Cole-Davidson
fitted
using relaxation
type. However,
time distributions
this was not found
possible
of in a
satisfactory
manner for all systems at any mixture composition.
description
of the results
which furthermore the dielectric
in terms of discrete
is advantageous
loss already
Debye
in comparing
Therefore
type spectral
components
different systems.
corrected for the conductivity
we prefer a
With
contribution,
Ci,
E”(W) being
a fit according
to
TiW
= !s si
d’(w)
i
was carried
1+T2w2 i
out and checked against the c’(w)
spectral components, It is difficult,
a formal analysis is obtained
however,
time ri and relaxation studied. certain
We
shall
composition_ systems
As
to interprete
on
with
the variation
described
will be considered
this leads
to some starting
the group
(b)
systems.
proceed
in detail
Using the minimnm
obtained
parameters
sense consistently
the aid of modified
of relaxation
parameters
in the following
sections,
first since they allow assumptions
results
for all the systems
analyses with the
parameters
in an analysis
which
chosen assumptions
are acceptable for the systems under consideration.
with the nonpolar
nearly
O-Xi), the total The
to decide simply
mixture
group
(a)
By analogy
requires
whether
more
or not the
400 with toluene or PEGDM
OKl dilution remains
the
used to analyze
number
PEG
by making
two
than the minimum
(4
of terms but allows
of
(relaxation
for a simple description.
on the mixture
Such a procedure
number
in that way.
the formally
strength Si) in a physical
therefore
assumptions
results
absorption
unchanged. relaxation is merely
liquid toluene, the shape of the PEG
At high enough strength, shifted
hi,
PEG
contents
is proportional
towards
higher
(mole
absorption fraction
to the PEG
curve
xPEG
2
concentration.
frequencies. However,
on further
lo9
loo
1
PEG
,
I
1
10
LOCI - ll33L3M
t
45% la
.I “PEO = 1
1
0.61 OAl
10
Fig_
I:
0
1WMHr
GHz
v-
Representative PEG400-PEGDM E ”
versus
only. rity).
absorption spectra of mixtures, dielectric LOSS frequency u.
dilution the total relaxation strength becomes less than the value ES: expected from cPEG proportionality; e.g. at xPEG = 0.4 there is ESi/ESf = 0.7. On the other hand, a remarkably simple mixture behaviour which appears to change almost linearly with mixture composition is exhibited by the polar-polar system PEG-FEGDM,
as may be seen from Fig. 1, where for clarity only fitting
curves are represented while the measured points are omitted. The results on this system suggest an analysis along the following lines. First, for the pure substances, a formal analysis is carried out which requires 4 terms for PEG 400 (where a minor low frequency term is nearly negligible) and 2 terma for PEGDM. Then
as
starting
assumption
for
the
mixtures the
Si
values
for
each
mixture
110
are
component Corresponding reduced
put
proportional
to
fits for PEG-toluene
as mentioned
posaible without
before,
the
respective
mixtures
cannot
substance
be achieved
concentration_ unless the Si are
while in the case of PEG-PEGDM
any additional
terms. They can be optimieed
fits
by variation
values and also by a slight variation of the Si values for some mixture This,
however,
still permits
to describe the PEG-PEGDM
with respect to the relaxation Generally, impairing
the
the
times
therefore tried to use constant mixture quality
range.
This
is just
is significantly
can
with
the
over
a
compositions.
as being “ideal”
(by
a factor
certain
PEG-PEGDM
range
two
it
was
over the whole
uncertainties,
of about
without
system
component
pussible within experimental
improved
parameters
varied
-ri values for each spectral
allowing the ri to be systematically The relaxation
be
In particular
quality.
mixtures
of the -ri
strengths of the mixture components.
relaxation
fit
are found
in the
but the fit variance)
by
varied-
obtained in that way for the two systems
are summarily
represented in Fig. 2.
(b) PEG The
200 with alcohols or water
absorption
monotonously
curves with
of
mixture
mixtures
of
composition
that as
group the
former
overview two examples
are given in Figs. 3,4 (omitting
1). While
with EGM
the mixtures
the gradual transition, case of PEG-water frequency absorption
do
not ones.
Fd
vary
(Fig. 3) resemble the PEGDM
,@
.a qualitatiye
the measured points ti.jn systems
(Fig.
Fig. 19 in
even a first glance at Fig. 4 shows a differing behaviour ip the
mixtures:
Here obviously
an add_itional contribution
to the low
appears at medium mixture ratios.
For the analysis of the group (b) data we adopt the tkk$ing the preceding
generally
PEG-PEGDM
taken from the pure mixture
system
proved to be ticeptabti,
components
assu,mption which for i&
fk&’ :Si values as
are put Illl(IroximateJy F).$$Q~$nal
to the
111 PEG 400 -Tot
0
1
2
0
1
=FEG
w
of
the
respective
component,
one
conceivable,
eince conformational
mixture
would
presupposes
probably
components,
self-association
fix mixtures
additional with EG
in
component that
a corresponding
five
manner
this
inkence
changee
Concerning
the
maximum
the
contribution
(as the PEG-toluene
strengths.
Concerning
can be drawn
PEG
system the second
on grounds
of their
view of Fige- 3,4 it is not unexpected constraint
spectral components_ and, in particular,
about
relaxation
comparative case8
concentration.
and related
lead to smaller
propertieSIn
in only some of the introducing
-
Relaxation parameters T. and S(log scales) versus PEG conc&ntrati;n for FEG400-toluene and -PEGDM mixtures. Full symbols stand for PEG, open symbols for PEGDM spectral components.
concentrafloti
shows)
2 mot/l
allows
for
an
Those complementary
with water.
ZLIGdyBiS
that
without
terms are required
The
a-
t
Figs_
100
Fl33200-EGM
I
already on
mentioned
The m3nuer
relaxation
ug
the
case
PEG
snmmtily
of
the
(b)
A
depicted
group
as
that
in
vary
Fig_
Generally.
with
to
as 6_
but
which
Among
obtained
for
of
the
for
the
the three
in
spectral
above-
effect
is
rich
This
the
absorption
alcohol
of
-ri
the PEG
as
hold
viscosity_
relaxation
pronounced
shift lees
initial
main
that
OHz
mixture
10
the
to
and
the
v-
~~chauget~
increasing data
the
with
1
impossible
PEGZOO-EGM
MHZ
peculiarity
Ioss
is
a
syateInf3
similar
an
dielectric ahow
of I>-
100
it is fouud ZOCr33G)_ noted
3
analyses
corresponding
be
PEG
content
of
time
Fig_
examples;
these
spectra
content,
(a)
frequencies.
PEG
inspection
parameters are
the
group
from
ccompnre
c3Har
therefore
for
the
relaxation
higher
from
Absorption -la*0
V
10
I
resulting
w-ithincreasi seen
towards
in
1
should
the
Xt
increasing
be
observedvzithMcOH-turea.
maximum
mixtures
can
dcoholdecrea.ses
systexns
viscosity-
ITLucture
PO@-EtOH
constant
as
times
3,4z
I
eventually
MHz
mostly
relaxation
composition
112
Fig.
‘i
I
7
t
5:
QJ
5
:
PEWO-EG
%EG-
PEG 200-EtOH
0
0
bV
l
5
0
mol/l
2II t
t.
I’
a’
5
A
I-
F 2;
4% I
A +t+ --l t++ a+* AAA
PEG200-H20
+. t__J t
A4
I -8 +a* l. AA
I ’ ’ ’ I ‘I
PEG MO- MeOH I , , , I
Relaxation parameters Ti and S. (log scales) vet8u8 PEG concentration for the group (b) mixtures given in thk captions. Full Bymbols concern spectral componenta ascribed to PEG, open eymbola thoec for the second mixture component, bar and cross symbols represent additional terms.
0
*a a L-I 0.1
1
x$8 8
r--l
%A
102
, eEG200-EGM
114 components
for PEG 200 two lower frequency terms of equal relaxation
necessary
could be used (in Fig. 5, full triangles for 7i and full diamonds
strengths
for the equal
‘i)Discussion The
dielectric
molecular subject
relaxation
dipoles. to
The
components.
Moreover
group
moments
(conformation,
correlations
(heteroassociation)
reflects the stochastic
permanent
intramolecular
intermolecular
discussion
spectrum
correlations
and correlation
for example, hydrogen
of moments
of both
of
may
bonds)
as it is also for the second
should be taken into account.
will be restricted
of PEG,
intramolecular
(self--association),
mutual
motion
mixture
be aud
mixture partners
In view of that variety of effects the
to the qualitative
consideration
of some
conspicuous
featurea. used in the data analysis implies that the correlation
The model assumption of each mixture The
finding
component
that
this
effects
stay unaltered in the mixture as in the pure bulk liquids.
model
is appropriate
in the case of PEG-PEGDM
is not
unexpected in consideration of the f&t that these chain molecules are closely similar. The same holds for EGM with
a nonpolar
PEG
are feasible.
liquid,
which is similar to a terminal section of PEG. on the other
conformational
The results on toluene mixtures
are still more pronounced the introduction,
hand,
however,
with other solvents
For mixtures
and related
changes
indicate just those changes,
such a~ dioxane
we shall desist from discussing
which
(41. As mentioned
the conformation
of
in
point in
the present paper. The finding
that a simple “ideal”
regard in particular are (i) PEG-EG PEG-EtOH component
the systems
and PEG-H20,
and PEG-MeOH,
mixture
with obvious
behaviour deviations
where complementary
is possible
at all suggests
from that behaviour. terms are required,
where the relaxation times ascribable
to
These and (ii)
to the alcoholic
do not follow the otherwise observed dependency on mixture composition.
116
(i) With mixture
EG a weak additional
ratios
(bar symbols
term on the low frequency side is found at medium
in Fig.
5).
This
is aleo the case with
water.
feature with the latter is a stronger additional
term with an intermediate
time in the region of the PEG
(cross symbols
a small
diol molecule
components
PEG
offer two associogenous
with these substances
to heterointeractions;
are known
amounts
and H20
observed
ascribable
main relaxation
of PEG
from
other
occurance
of
molecules.
We
pyrrolidone
studies
complementary
somewhat
passes through observed water
relaxation
addition
term
though
a maximum
region
admixtures
the
is
however,
not
special
as with water also with
are unusual in character.
time
increases
with
to apply
to pure water,
at about cPEG
another
spectral
= 3.5 mol/l.
[7]
that to
the
protic
methyl-
of which
to that description resulting
[15,16],
We confine our
relaxation
content,
with
mode
which
approximately
change
As
from
strength
behavionr
is also
consequently [14,15].
represents
the water
constant
relaxation
more
drastically
on
We have reanalyzed
our
mode which is found to be possible, strengths
starting
and its relaxation A similar
terms.
to water. It is often possible for the
description
components
strengths
the PEG
of the solute than in the former description
compare
small
the effect is weaker in these cases and
of various other substances
relaxation
data according
of relatively
to the more intense of the two complementary
20 ps as extrapolated
by several
the
contributions
interactions
relaxation
on addition
rich
times,
its
above
being
water effect be considered in some detail. The question may be
for the moment
5 shows,
and the iufluence
[13]. It should be stressed,
an intermediate
raised as to whether PEG-H20
Fig.
with that fact,
term is missing.
Let the pronounced
attention
protic sites. The additional
not only been inferred from dielectric
relaxation
[4] and tetramethylurea,
the low frequency
in Fig. 5). Both EG as
may be connected
[11,12],
measurements
have found
relaxation
hydrogen bonds between small donor molecules and
on water has previously
but also from ultrasonic
Another
with
some
previous
too, in order to
results
see Fig. 6_ It turns out that on the water concentration
on
other
scale the
116
80
I
I
60-
t
si
c
v:
VV do 0
v
20w
e
30
6:
to just the same extent
intensity
[14,15])_ This “bulk” is relatively
mixtures depicted
6)_ A
process ie gradually
still
slower
the diehxtric
the relaxation in bulk
water
substituted
third
term
position
of the aqueous
of the relaxation
(see cross symbols
(for f&her
by a (ca)
a loss in
shows
examples
component
INX
20 pa process, which
compare e-g. diethyleneglycol
spectral
of the PEG-H20 component:
while
generally artsignedto affected (“hydration”) The
water,
(about
aqueous
70 ps)
is not
to water is quationable.
behavioux
vanishes
of pure
as with other admixtures
in Fig_ 6 since its assignment
On the whole
operative
ie characteristic
weak Ear the present case of PEG,
(Fig.
concerning
Qlv ,o 50 mol/l
Relaxation strengths S. of some water rkch mixtures accordin; to a modified description mode, where relaxation Full symbols: times are nearly constant. RI20 ps. O IO ps. open symbols: ~~ TAtueous mixtures with the following substanceste PEG200 (this work); m poly1200 and 40000 [16];
procest3, which
10 ps relaxation
-
Oo
I 40
0
-
V
*v
FiR.
I’ v
strength
a slower
system is not exceptional
The relaxation one is built
process which is
up,
which
may
be
water. maximum
in Fig. 5) corresponds
of the intermediate
to a ratio of about
additional
6.8 mol H20
per
117 mol PEG,
equivalently
measurements seems
about 3 H20
indicative
enable
characteristic
due
fast
motion
This
should,
of the involved
water
For PEG-
proportion
only.
component
heteroassociation,
EtOH
(about
involving
and PEG-MeOH
thus the mean alcohol of the main
2000
water
model
time
EtOH
the relaxation state,
residence within
which
decrease time
(open upright such
MeOH,
that
molecules
to
20 ps
is
triangles
is shortened of EtOH
of heteroassociation
just
caused
by
molecule
network.
However,
since
In that
has
molecules
of PEG.
containing
a more
of a lifetime
heteroassociation,
in
Additional systems,
provided
so that the
state
is shorter
than
of the alcohol
relaxation
time
main relaxation
the influence
time (full triangles)
of PEG
on the alcohols
manner from that on water
Support of this work by the Fonds der Chemischen acknowledged.
in
by PEG,
from that. It might be, however,
The convergence
are
it is the decrease
[18]. In terms
in a heteroassociated
respect
thns
correlation,
former
on addition
increasing
it is
strengths
is affected
the
and MeOH
in Fig. 5) with the PEG
an inference.
gratefully
which
moment
the alcohol
possibly
(apart
Possibly
relaxation
the alcohol
as often supposed
obviously
of an alcohol
differs in a qualitative
than
in the analysis
the selfasoclated
supports
about
time is a measure of the residence time of alcohol
are not required
lifetime
(i.e.
ps) is here observed
yield
is only little influenced.
than the latter,
there is no direct indication a
infer that
which indicates
rather
structure
the associated terms
molecules
enough
water.
the analyses
One might
structure,
relaxation
with
complicated
be loose
It appears to be special for protic liquids.
to concentration.
markedly
IR and NMR
[17]. Such a number
however,
affected in another manner than the normal “hydration” (ii)
From
per repeat unit have been estimated
additional
with EG
“bridging”
to
unit of PEG.
time)_
low frequency
from water)
per ether repeat
of a direct interaction.
a relatively
The
2 H20
Indnstrie
is
118
PI
G. Klages
and M. Strasemann,
PI PI
N_ Koizumi,
J- Chem.
M- Davies,
G. Williams
141
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Gattmann,
82 (1978),
R
Podbieleki,
64 (1960), Colloid
575
P&m.
Sci.
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Ber. Bunsenges.
U. Kaatze,
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G-
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1990 R
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and U. Terveer,
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112
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330
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Smalyanskii,
21
DIELECTRIC
105
RELAXATION
MIXTURES
OF SOME
CONTAINING
Institut
22
M. Stockhausen
fifr Physikalische
January
The permittivity 30
MHz
and
(PEGDM); ethanol, from
an
mixture
GE2:
PEG
200
contributions
FZG
with
or water.
400
(Germany)
with
The
2
0)
toluene
description
or PEG
4CO dimethylether
to
ethyleneglycol,
of the dielectric
superposition
(PEG-PEGDM)
(PEG-H
has been measured at 20 OC between
ethyleneglycolmonomethylether,
unperturbed
components
MCmster,
1991)
72
apparently
and G_ SchiItz
Chemie der Universitat
of the following mixtures
methanol
AS
COJMPONIZNT
Miinster
LIQUID
POL YETEYLENEGLYCOL
ONE E. Wessling,
BINARY
of
spectra
contributions
the occurance
ranges
from
of strong
both
additional
which are ascribable to heteroassociation.
Introduction Chain molecules, dielectric moments (PEG),
even those with only terminal dipole moments,
relaxation are
behaviour
distributed
H(OCH2CH2)pOH.
temperature,
are widely
0167-7322/91/$03.50
8
exhibit
a non-Debye
in the liquid state [x]. All the more this is the case if
along
the
chain
backbone,
These substances, applied
not
least
as
with
which for p s
because
of their
1991 -ElfmvierSciencePubliehemB.V.
polyethyleneglycols
10 are liquids at room water
solubility.
Allrights~rved
The
dynamic
dielectric
aqueous
ones
information mixture
properties
systems
may
hydrogen
The absorption be described
by
of
segmental
continuous
relaxation
components. and
noticed
[lo])
motions
frequency
opposite
time
dietherated
concerning region
short)
from
of the
with increasing
This
properties
may
systems.
solute
and
meaningful those
information previous
studies of in
terminal
be
revealed
of PEGs
and
of
solvent
concerning
studies mostly
substances
and
hydroq
coils,
probably
groups.
A
relaxation
particularly
(e.g.
region is mainly
within the flexible
PEG
the
due to
while the
inter-
peculiarity
and
already
time (which anyway
as viscosity
is
varies in the
increasing
weight
interpretation
of the
itself but on the mutual
in the
dynamic
soIvents,
which
dielectric
in particular
cannot
assuming
that
such
therefore
in particular
worthwhile
to
the variation
laid stress on the variation
a
interaction
properties water,
unambiguously
at all. In order to attain a better understanding seems
of discrete
process.
contributions,
it
a sum
related
absorption
motion
chain length,
in polar
spectrum
It CZLIIeither
it has been inferred from comparative
PEGS
the
or by
is not aimed at a more thorough
of the polymer
absorption
systems
from
interactions,
but unstructured.
decrease is likely to result from the relatively
possibly
Solutions
unstructured
Apart
chain, dielectric
distributions
the ether oxygens
arises
present communication
which
of
is broadened
Qualitatively
of the chain ether group relaxation
dielectric
in particnlar
years
of intermolecular
that the higher frequency
association
sense.
solutions,
many
of the PEG
in early work is the decrease of the effective
surprisingly
The
for
to the knowledge
of pure PEGs
mono-
intramolecular
and dynamics
contribute
and of PEG
attention
spectrum
polypropyleneglycoi
lower
attracted
[2-5]
bonding effecta-
type spectral
studies
have
[3,5-Q],
on the conformation
particular
Debye
of pure PEGS
be
of
show
of the dielectric
of the
of the PEG
more
mixture
mixture again
resolved
subdivision
gather
effects
an into
might
be
behaviour
experimental partner,
chain length.
while
107
Here
we report
relative
molar
nonpolar with
on PEG
mixture
B~~IIM
using
mass of 400 or 200. They may be arranged
solvent and with a dietherated
a fkw protic liquids
covering
(a)
some results
including
the whole mixture
derivative
PEGB
in two groups:
as second mixture
water_ The following
400 -
toluene
PEG
400 -
polyethyleueglycol4OO-dimethylether
a mean
(a) with a
component,
(b)
systems have been studied
range (except for the first mentioned
PEG
with
example) :
(PEGDM),
H3C(OCH2CH2)pOCH3 (b)
PEG
200 -
ethyleneglycolmonomethylether
PEG
200 -
ethyleneglycol
PEG
200 -
ethanol (EtOH)
PEG
200 -
methanol
PEG
200 -
H20_
The complex range
between
experimental The
30 MHz uncertainty
chemicals
further
The
permittivity
were
(EG),
(EGM),
H3COCsCH2OH
HOCH2C%0H
(MeOH)
of the liquids and 72 GHz
was measured
employing
at 12 spot frequencies
different
experimental
in the
setups. The
is a few percent. All measure ments are at 20 OC. from
Aldrich,
Fluka
aud
Merck.
They
were
used
without
purification.
permittivity
the Cole-Cole
data
were tentatively
or Cole-Davidson
fitted
using relaxation
type. However,
time distributions
this was not found
possible
of in a
satisfactory
manner for all systems at any mixture composition.
description
of the results
which furthermore the dielectric
in terms of discrete
is advantageous
loss already
Debye
in comparing
Therefore
type spectral
components
different systems.
corrected for the conductivity
we prefer a
With
contribution,
Ci,
E”(W) being
a fit according
to
TiW
= !s si
d’(w)
i
was carried
1+T2w2 i
out and checked against the c’(w)
spectral components, It is difficult,
a formal analysis is obtained
however,
time ri and relaxation studied. certain
We
shall
composition_ systems
As
to interprete
on
with
the variation
described
will be considered
this leads
to some starting
the group
(b)
systems.
proceed
in detail
Using the minimnm
obtained
parameters
sense consistently
the aid of modified
of relaxation
parameters
in the following
sections,
first since they allow assumptions
results
for all the systems
analyses with the
parameters
in an analysis
which
chosen assumptions
are acceptable for the systems under consideration.
with the nonpolar
nearly
O-Xi), the total The
to decide simply
mixture
group
(a)
By analogy
requires
whether
more
or not the
400 with toluene or PEGDM
OKl dilution remains
the
used to analyze
number
PEG
by making
two
than the minimum
(4
of terms but allows
of
(relaxation
for a simple description.
on the mixture
Such a procedure
number
in that way.
the formally
strength Si) in a physical
therefore
assumptions
results
absorption
unchanged. relaxation is merely
liquid toluene, the shape of the PEG
At high enough strength, shifted
hi,
PEG
contents
is proportional
towards
higher
(mole
absorption fraction
to the PEG
curve
xPEG
2
concentration.
frequencies. However,
on further
lo9
loo
1
PEG
,
I
1
10
LOCI - ll33L3M
t
45% la
.I “PEO = 1
1
0.61 OAl
10
Fig_
I:
0
1WMHr
GHz
v-
Representative PEG400-PEGDM E ”
versus
only. rity).
absorption spectra of mixtures, dielectric LOSS frequency u.
dilution the total relaxation strength becomes less than the value ES: expected from cPEG proportionality; e.g. at xPEG = 0.4 there is ESi/ESf = 0.7. On the other hand, a remarkably simple mixture behaviour which appears to change almost linearly with mixture composition is exhibited by the polar-polar system PEG-FEGDM,
as may be seen from Fig. 1, where for clarity only fitting
curves are represented while the measured points are omitted. The results on this system suggest an analysis along the following lines. First, for the pure substances, a formal analysis is carried out which requires 4 terms for PEG 400 (where a minor low frequency term is nearly negligible) and 2 terma for PEGDM. Then
as
starting
assumption
for
the
mixtures the
Si
values
for
each
mixture
110
are
component Corresponding reduced
put
proportional
to
fits for PEG-toluene
as mentioned
posaible without
before,
the
respective
mixtures
cannot
substance
be achieved
concentration_ unless the Si are
while in the case of PEG-PEGDM
any additional
terms. They can be optimieed
fits
by variation
values and also by a slight variation of the Si values for some mixture This,
however,
still permits
to describe the PEG-PEGDM
with respect to the relaxation Generally, impairing
the
the
times
therefore tried to use constant mixture quality
range.
This
is just
is significantly
can
with
the
over
a
compositions.
as being “ideal”
(by
a factor
certain
PEG-PEGDM
range
two
it
was
over the whole
uncertainties,
of about
without
system
component
pussible within experimental
improved
parameters
varied
-ri values for each spectral
allowing the ri to be systematically The relaxation
be
In particular
quality.
mixtures
of the -ri
strengths of the mixture components.
relaxation
fit
are found
in the
but the fit variance)
by
varied-
obtained in that way for the two systems
are summarily
represented in Fig. 2.
(b) PEG The
200 with alcohols or water
absorption
monotonously
curves with
of
mixture
mixtures
of
composition
that as
group the
former
overview two examples
are given in Figs. 3,4 (omitting
1). While
with EGM
the mixtures
the gradual transition, case of PEG-water frequency absorption
do
not ones.
Fd
vary
(Fig. 3) resemble the PEGDM
,@
.a qualitatiye
the measured points ti.jn systems
(Fig.
Fig. 19 in
even a first glance at Fig. 4 shows a differing behaviour ip the
mixtures:
Here obviously
an add_itional contribution
to the low
appears at medium mixture ratios.
For the analysis of the group (b) data we adopt the tkk$ing the preceding
generally
PEG-PEGDM
taken from the pure mixture
system
proved to be ticeptabti,
components
assu,mption which for i&
fk&’ :Si values as
are put Illl(IroximateJy F).$$Q~$nal
to the
111 PEG 400 -Tot
0
1
2
0
1
=FEG
w
of
the
respective
component,
one
conceivable,
eince conformational
mixture
would
presupposes
probably
components,
self-association
fix mixtures
additional with EG
in
component that
a corresponding
five
manner
this
inkence
changee
Concerning
the
maximum
the
contribution
(as the PEG-toluene
strengths.
Concerning
can be drawn
PEG
system the second
on grounds
of their
view of Fige- 3,4 it is not unexpected constraint
spectral components_ and, in particular,
about
relaxation
comparative case8
concentration.
and related
lead to smaller
propertieSIn
in only some of the introducing
-
Relaxation parameters T. and S(log scales) versus PEG conc&ntrati;n for FEG400-toluene and -PEGDM mixtures. Full symbols stand for PEG, open symbols for PEGDM spectral components.
concentrafloti
shows)
2 mot/l
allows
for
an
Those complementary
with water.
ZLIGdyBiS
that
without
terms are required
The
a-
t
Figs_
100
Fl33200-EGM
I
already on
mentioned
The m3nuer
relaxation
ug
the
case
PEG
snmmtily
of
the
(b)
A
depicted
group
as
that
in
vary
Fig_
Generally.
with
to
as 6_
but
which
Among
obtained
for
of
the
for
the
the three
in
spectral
above-
effect
is
rich
This
the
absorption
alcohol
of
-ri
the PEG
as
hold
viscosity_
relaxation
pronounced
shift lees
initial
main
that
OHz
mixture
10
the
to
and
the
v-
~~chauget~
increasing data
the
with
1
impossible
PEGZOO-EGM
MHZ
peculiarity
Ioss
is
a
syateInf3
similar
an
dielectric ahow
of I>-
100
it is fouud ZOCr33G)_ noted
3
analyses
corresponding
be
PEG
content
of
time
Fig_
examples;
these
spectra
content,
(a)
frequencies.
PEG
inspection
parameters are
the
group
from
ccompnre
c3Har
therefore
for
the
relaxation
higher
from
Absorption -la*0
V
10
I
resulting
w-ithincreasi seen
towards
in
1
should
the
Xt
increasing
be
observedvzithMcOH-turea.
maximum
mixtures
can
dcoholdecrea.ses
systexns
viscosity-
ITLucture
PO@-EtOH
constant
as
times
3,4z
I
eventually
MHz
mostly
relaxation
composition
112
Fig.
‘i
I
7
t
5:
QJ
5
:
PEWO-EG
%EG-
PEG 200-EtOH
0
0
bV
l
5
0
mol/l
2II t
t.
I’
a’
5
A
I-
F 2;
4% I
A +t+ --l t++ a+* AAA
PEG200-H20
+. t__J t
A4
I -8 +a* l. AA
I ’ ’ ’ I ‘I
PEG MO- MeOH I , , , I
Relaxation parameters Ti and S. (log scales) vet8u8 PEG concentration for the group (b) mixtures given in thk captions. Full Bymbols concern spectral componenta ascribed to PEG, open eymbola thoec for the second mixture component, bar and cross symbols represent additional terms.
0
*a a L-I 0.1
1
x$8 8
r--l
%A
102
, eEG200-EGM
114 components
for PEG 200 two lower frequency terms of equal relaxation
necessary
could be used (in Fig. 5, full triangles for 7i and full diamonds
strengths
for the equal
‘i)Discussion The
dielectric
molecular subject
relaxation
dipoles. to
The
components.
Moreover
group
moments
(conformation,
correlations
(heteroassociation)
reflects the stochastic
permanent
intramolecular
intermolecular
discussion
spectrum
correlations
and correlation
for example, hydrogen
of moments
of both
of
may
bonds)
as it is also for the second
should be taken into account.
will be restricted
of PEG,
intramolecular
(self--association),
mutual
motion
mixture
be aud
mixture partners
In view of that variety of effects the
to the qualitative
consideration
of some
conspicuous
featurea. used in the data analysis implies that the correlation
The model assumption of each mixture The
finding
component
that
this
effects
stay unaltered in the mixture as in the pure bulk liquids.
model
is appropriate
in the case of PEG-PEGDM
is not
unexpected in consideration of the f&t that these chain molecules are closely similar. The same holds for EGM with
a nonpolar
PEG
are feasible.
liquid,
which is similar to a terminal section of PEG. on the other
conformational
The results on toluene mixtures
are still more pronounced the introduction,
hand,
however,
with other solvents
For mixtures
and related
changes
indicate just those changes,
such a~ dioxane
we shall desist from discussing
which
(41. As mentioned
the conformation
of
in
point in
the present paper. The finding
that a simple “ideal”
regard in particular are (i) PEG-EG PEG-EtOH component
the systems
and PEG-H20,
and PEG-MeOH,
mixture
with obvious
behaviour deviations
where complementary
is possible
at all suggests
from that behaviour. terms are required,
where the relaxation times ascribable
to
These and (ii)
to the alcoholic
do not follow the otherwise observed dependency on mixture composition.
116
(i) With mixture
EG a weak additional
ratios
(bar symbols
term on the low frequency side is found at medium
in Fig.
5).
This
is aleo the case with
water.
feature with the latter is a stronger additional
term with an intermediate
time in the region of the PEG
(cross symbols
a small
diol molecule
components
PEG
offer two associogenous
with these substances
to heterointeractions;
are known
amounts
and H20
observed
ascribable
main relaxation
of PEG
from
other
occurance
of
molecules.
We
pyrrolidone
studies
complementary
somewhat
passes through observed water
relaxation
addition
term
though
a maximum
region
admixtures
the
is
however,
not
special
as with water also with
are unusual in character.
time
increases
with
to apply
to pure water,
at about cPEG
another
spectral
= 3.5 mol/l.
[7]
that to
the
protic
methyl-
of which
to that description resulting
[15,16],
We confine our
relaxation
content,
with
mode
which
approximately
change
As
from
strength
behavionr
is also
consequently [14,15].
represents
the water
constant
relaxation
more
drastically
on
We have reanalyzed
our
mode which is found to be possible, strengths
starting
and its relaxation A similar
terms.
to water. It is often possible for the
description
components
strengths
the PEG
of the solute than in the former description
compare
small
the effect is weaker in these cases and
of various other substances
relaxation
data according
of relatively
to the more intense of the two complementary
20 ps as extrapolated
by several
the
contributions
interactions
relaxation
on addition
rich
times,
its
above
being
water effect be considered in some detail. The question may be
for the moment
5 shows,
and the iufluence
[13]. It should be stressed,
an intermediate
raised as to whether PEG-H20
Fig.
with that fact,
term is missing.
Let the pronounced
attention
protic sites. The additional
not only been inferred from dielectric
relaxation
[4] and tetramethylurea,
the low frequency
in Fig. 5). Both EG as
may be connected
[11,12],
measurements
have found
relaxation
hydrogen bonds between small donor molecules and
on water has previously
but also from ultrasonic
Another
with
some
previous
too, in order to
results
see Fig. 6_ It turns out that on the water concentration
on
other
scale the
116
80
I
I
60-
t
si
c
v:
VV do 0
v
20w
e
30
6:
to just the same extent
intensity
[14,15])_ This “bulk” is relatively
mixtures depicted
6)_ A
process ie gradually
still
slower
the diehxtric
the relaxation in bulk
water
substituted
third
term
position
of the aqueous
of the relaxation
(see cross symbols
(for f&her
by a (ca)
a loss in
shows
examples
component
INX
20 pa process, which
compare e-g. diethyleneglycol
spectral
of the PEG-H20 component:
while
generally artsignedto affected (“hydration”) The
water,
(about
aqueous
70 ps)
is not
to water is quationable.
behavioux
vanishes
of pure
as with other admixtures
in Fig_ 6 since its assignment
On the whole
operative
ie characteristic
weak Ear the present case of PEG,
(Fig.
concerning
Qlv ,o 50 mol/l
Relaxation strengths S. of some water rkch mixtures accordin; to a modified description mode, where relaxation Full symbols: times are nearly constant. RI20 ps. O IO ps. open symbols: ~~ TAtueous mixtures with the following substanceste PEG200 (this work); m poly1200 and 40000 [16];
procest3, which
10 ps relaxation
-
Oo
I 40
0
-
V
*v
FiR.
I’ v
strength
a slower
system is not exceptional
The relaxation one is built
process which is
up,
which
may
be
water. maximum
in Fig. 5) corresponds
of the intermediate
to a ratio of about
additional
6.8 mol H20
per
117 mol PEG,
equivalently
measurements seems
about 3 H20
indicative
enable
characteristic
due
fast
motion
This
should,
of the involved
water
For PEG-
proportion
only.
component
heteroassociation,
EtOH
(about
involving
and PEG-MeOH
thus the mean alcohol of the main
2000
water
model
time
EtOH
the relaxation state,
residence within
which
decrease time
(open upright such
MeOH,
that
molecules
to
20 ps
is
triangles
is shortened of EtOH
of heteroassociation
just
caused
by
molecule
network.
However,
since
In that
has
molecules
of PEG.
containing
a more
of a lifetime
heteroassociation,
in
Additional systems,
provided
so that the
state
is shorter
than
of the alcohol
relaxation
time
main relaxation
the influence
time (full triangles)
of PEG
on the alcohols
manner from that on water
Support of this work by the Fonds der Chemischen acknowledged.
in
by PEG,
from that. It might be, however,
The convergence
are
it is the decrease
[18]. In terms
in a heteroassociated
respect
thns
correlation,
former
on addition
increasing
it is
strengths
is affected
the
and MeOH
in Fig. 5) with the PEG
an inference.
gratefully
which
moment
the alcohol
possibly
(apart
Possibly
relaxation
the alcohol
as often supposed
obviously
of an alcohol
differs in a qualitative
than
in the analysis
the selfasoclated
supports
about
time is a measure of the residence time of alcohol
are not required
lifetime
(i.e.
ps) is here observed
yield
is only little influenced.
than the latter,
there is no direct indication a
infer that
which indicates
rather
structure
the associated terms
molecules
enough
water.
the analyses
One might
structure,
relaxation
with
complicated
be loose
It appears to be special for protic liquids.
to concentration.
markedly
IR and NMR
[17]. Such a number
however,
affected in another manner than the normal “hydration” (ii)
From
per repeat unit have been estimated
additional
with EG
“bridging”
to
unit of PEG.
time)_
low frequency
from water)
per ether repeat
of a direct interaction.
a relatively
The
2 H20
Indnstrie
is
118
PI
G. Klages
and M. Strasemann,
PI PI
N_ Koizumi,
J- Chem.
M- Davies,
G. Williams
141
H_ Utzel,
and G.D.
V. L6nnecke-Gabel,
WI
U. Kaatze,
0.
Z. Elektrochem-
and M. Stockhausen,
PhD thesis Ghttingen
Gattmann,
82 (1978),
R
Podbieleki,
64 (1960), Colloid
575
P&m.
Sci.
U_ Kaatze,
Ber. Bunsenges.
U. Kaatze,
Progr. Colloid Polym.
PI
G-
Masszi,
1990 R
Pottel
and U. Terveer,
J. Phys-
112
PI PI
(1986),
1403
625
Loveluck,
E. Dachwitz
30a (1975),
330
151
Chem.
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E. Wessling,
268 (1990),
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Lakatos,
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21