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Dielectric relaxation in propionic acid-tri-n-butylamine system
159
Advances in Molecular Relaxation and Interaction Processes, 22 (1982) 159-165 Elsevier Scientific Publishing Company, Amsterdam - Printed in The Netherlands
DIELECTRIC
M.
RELAXATION
Pajdowska
Institute
IN
PROPIONIC
ACID-TRI-N-BUTYLAMINE
SYSTEM
and L. Sobczyk of Chemistry,
University
of Wroclaw,
50-385
Wroclaw,
Poland (Received 7 September 1981) ABSTRACT The range
complex
electric
100 MHz-2GHz
-n-butylamine
permittivity
have been
systems
and viscosity
measured
of varying
composition.
relaxation
time and its distribution
especially
for 1:l species.
over
for the propionic Both,
indicate
the frequency acid-
the value
a remarkable
triof the
aggregation
INTRODUCTION Carboxylic techniques
acid-
both
amine
systems
in solution,
[l-71.
In such
systems
bonds,
leading
to the formation
position, binary The
the most
mixtures
studies
a strong
stable
of a proton
solvation
and
interaction
and
takes
presumably
bonds
self-solvation
and,
place
mixtures
via hydrogen com-
to be present
spectra
revealed
in particular,
equilibrium
In r6,71.
specific
the possible
and furthermore - creation
processes
various
1:l and 2:l adducts.
and infra-red
transfer
using
in binary
of miscellaneous
are also postulated
moments
of O-H.. .N hydrogen
features existence
studied
solvents
of complexes
being
3:l complexes
of dipole
have been
in inert
- due to
of free ions
111-151. The
aim of the present range
frequency
-n-butylamine information processes
related
(TBA)
work
mixtures of varying
on the structure which
processes.
for
could
Searches
is of
to study
composition.
of these
be ascribed
jumping
acid
remained,
over
the dispersion
(PrAH)
We hoped
liquids
and tri-
to gain
new
and on the relaxation
to the kinetics
for the dielectric
to the proton
E*(O)
propionic
response
of proton
which
might
so far, without
0378-4487/82/0000~000/$02.75 0 1982 Elsevier Scientific Publishing Company
transfer be directly
success.
160 EXPERIMENTAL The mixtures object
of carboxylic
for dielectric
and electric
work
the frequency method
range
of 100 MHz
and 5 sun depth
determination -terminal
which
connects
in our experiment
range
at 2 GHz
E’
+5%
for
been measured
of E*(W) have been
RESULTS
and
performed
For all systems
except
distribution
distinct
feature
we applied
cos h
-1
ratio
of
the liquid
line. The
allow
for the
of a two-portresults
the
obtained
+ 2% for E' and f 5% for E" E”
The viscosity
.
viscometer.
of
In addition
while
the liquidswas
the measurements
for PrAH + TBA complexes
in benzene.
whereas
in benzene
of the defined
relation
processes,
in the numerical
reflects
1 the behaviour
1
E’
far binary From
values
2 evaluated
mixtures
the plot
pure
to about
diagram
analysis:
time and
6
: TBA system
as an example
and the Fuoss-Kirkwood for respective
plot.
systems
~~ and 6 are given.
ratio
decrease
increases,
are long
of 17 against value
and
in the mean
Generally
the molar
fraction,
noticing
is, approximately,
relaxation
the relaxation
do not correlate
of n corresponds
3:l. It is worth
components
any
Hence
from monodispersivity.
are compared
show a striking
that the maximum
equal
of relaxation
of the 1:l PrAH
~~ as the acid/amine
it appears
evaluation the deviation
on the Cole-Cole and E"
a sig-
without
(1)
for a graphical which
in Table
of both
solutions
time is observed
=*ln.L!$tZ
The data obtained
cosity.
dilute
E’ ’
is illustrated In Table
the more
of the separation
E" max _
allows
In Fig.
ratio
capacitance
of 4-8 mm diameter
the theory
of the relaxation
the Fuoss-Kirkwood
coefficient,
times
wave
In
out over
AND DISCUSSION
nificant
time
k 7% for
by an Ostwald
the lumped
the end of a coaxial
levels
at 100 MHz
losses
reactivity.
has been carried
capacitor
by using
The confidence
a difficult
C161. In this method
shift and standing
of the impedance
network.
of chemical
glass to
represent
of high permittivity
- 2 GHz using
in our laboratory
of phase
amines
of E*(W)
is put into a cylindrical
measurements
which
because
and because
the measurement
developed
sample
studies
conductivity
the present
acids with
with
vis-
shown in Fig. 2
to the PrAH/TBA
that
the same.
the viscosity
161
A cos h-’
(0)
cmuc
I
E”
1
2-
l-
E” (b)
84-
Fig. 1. Cole-Cole (a) and Fuoss-Kirkwood acid TBA system.
(b) plots for 1:l propionic
In order to compare the relaxation times with the volume of defined species it is necessary to assume some theoretical model. From the literature data it follows that the best agreement between the effective molecular volume and that calculated from the dielectric relaxation time is obtained from the following relation [171:
T
u=
-2 nil
1 73 - 1o12
(2)
162
20 -
10 -
0+
I
Fig. 2. Viscosity PrAH - TBA system.
TABLE
System
- values v(MH2)
6:l
binary mixture
against
molar
fraction
of PrAH
1.0
for the
at 298 K E'
E"
162 250 520 1000 2000
7.44 6.47 5.33 4.47 4.42 3.78
4.0 4.16 3.08 1.92 1.51 0.91
100 162 250 520 1000 2000
9.10 8.22 6.33 5.82 3.92 4.15
6.33 6.20 4.06 3.35 2.70 1.11
100
162 250 520 1000 2000
9.45 8.76 6.94 6.59 4.38 4.50
5.37 5.84 4-69 3.95 2.99 1.29
100 162 250 520 1000 2000
10.59 9.79 7.15 6.73 4.35 4.32
4.37 6,03 7.23 S-25 3.68 1.63
100
111 binary mixture
3:l binary mixture
plotted
XA
1.
E’ and E"
2:l binary mixture
08
a2
System
1.6M PrAH in TBA
2.2M PrAH in TBA
1.6M complex in benzene
l.OM complex in benaene
v(MH.2)
E'
E"
100 165 250 600 1000 1600
3.79 3.52 3.32 3.00 3.12 2.90
0.85 0.69 0.93 0.53 0.44 0.49
100 165 250 600 1000 1600
4.52 3.98 3.69 3.25 3.29 3.40
1.58 1.38 1.28 0.65 0.54 0.71
100 165 250 730 1000 2000
6.75 5.86 5..87 4.29 4.03 3.64
1.11 1.46 1,88 1.85 1.54 1.36
100 165 250 730 1000 1666
5.00 4.74 4.48 3.91 3.64 3.33
0.66 0.68 0.94 1.33 l-05 1.01
163
TABLE
2.
Mean macroscopic relaxation time ~~ and the % Fuoss-Kirkwood parameter for PrAHsTBA systems. T=298
K
System
To'Ps
1:l 2:l 3:l 6:l 1.6M l.OM 2.2M 1.6M
binary mixture binary mixture binary mixture binary mixture complex in benzene complex in benzene PrAH in TBA PrAH in TBA
TABLE
3.
3150 1991 1600 760 398 282 2500 700
% 0.64 0.79 0.76 0.89 0.72 0.86 0.65 1.0
Molecular volumes of PrAH.TBA complexes VM compared with those calculated from dielectric relaxation times VD
cz31
System 1:l 2:l 3:l 6:l
binary binary binary binary
mixture mixture mixture mixture
528 659 790
?493 1712 994 1186
where Tu (from Powles) equals
2EO+ E, F--, ~~ being the macroscopic
relaxation time, while nU =O,l
n (from Debye)
0
where n is the macro-
scopic viscosity. Moreover, analysis of the literature data shows a distinctly positive deviation from equation (2) for polar associated liquids. In Table 3 the effective molecular volumes are compared with those calculated from dielectric relaxation time for various composition of liquids. Therefore, the liquids of 1:l ratio are, in terms of molecular volumes,. the most associated. The lowest % parameter occurs in conjunction with the highest relaxation time, thereby confirming the largest distribution of molecular volumes of reorientating species. In benzene solutions the PrAHtTBA system behaves normally but at a higher concentrations ho increases and % parameter decreases providing evidence of the aggregation process. The aggregation process is also observed in solutions .with excess TBA, where only 1:l complexes are formed., Considering the possible mechanisms of dielectric relaxation in our systems, the structural relaxation cannot be omitted L19, 20 1.
164
The
fact that, with
could
indioate
the ordered
excess PrAH, the
such a mechanism
structure
of
relaxation
since an
time decreases
excess
the liquid. However,
should disturb
at excess
of
amine which can be treated as a neutral solvent the observed relaxation time is again very long. Thus, one can suggest that there are relatively large molecular clusters with a life-time considerably exceeding the dielectric relaxation time. The distribution of relaxation times as a consequence of a statistical distribution of molecular masses seems to be in agreement with such an argument. The appearance of an expected additional relaxation process connected with proton motion is still not clear. Dielectric losses at the highest frequencies used in this work disappea.r but the ~~ value is considerably higher than ni which could indicate some faster process to be expected beyond the GHz frequency range. Table 4 contains collected data on e--n:
for the investigated
systems. TABLE 4. Molar ratio PrAH/TBA
EC0
1:l 2:l 3:l 6:l
4. 4.4 4.2 3.9
2 "D 2.0497 2.0598 2.0535 2.0135
2 ccc-n D 1.95 2.34 2.15 1.89
It is difficult to judge whether such remarkable increments can be entirely assigned to fairly well known effects like Poley absorption C201 and intramolecular motions giving rise to a change of dipole moment. The observed increment is close to those found for hydrogen bonded strongly associated liquids L21-231. Presumably, the main reason for the large E, - ni values in all systems of this type is the anomalous polarizability related to various protonic vibrations which are distinguished by .a high intensity in the absorption spectra.
REFERENCES 1 2 3 4
J.W. Smith, M.G. Victoria, J. Chem. Sot. 77(1968) 4474. DeLos F. DeTar, R.N. Novak, J. Am. Chem. Sot. 92(1970) 1361. G.M. Barrow, J. Am. Chem. Sot. 78(1956) 5802. M.F. Claydon, N. Sheppard, Chem. Comm. 43(1969).
165
5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23
S.L. Johnson, K.A. Rumon, J. Phys. Chem. 69(1965) 74. F. Kohler, E. Liebermann, G. Miksch, Ch. Keinz, J. Phys. Chem. 76(1976) 2764. M. Bobik, Abv. Mol. Relax. Proc. ll(1977) 191. M. Davies, L. Sobczyk, J. Chem. Sot. (1962) 3000 S.R. Gough, H.A. Price, J. Phys. Chem. 73(1969) 459. E. Jakusek, H. Koxodziej, L. Sobczyk, Acta Phys. Polon. 38A(1970) 57. E. Jakusek, M. Pajdowska, L. Sobczyk, Chem. Phys. 9(1975) 205. V.K. Venkatesen, C.V. Suryanarayna, J. Phys. Chem. 60(1956) 777. K.C. Molhotra, R.G. Sud, J. Inorg. Nucl. Chem. 38(1976) 775. J. Hurwic, J. Michalczyk, K. Pogorzelska, Roczniki Chemii 31 (1957) 265. P. Huyskens, N. Felix, A. Janssens, F. van den Broeck and F. Kapuku, J. Phys. Chem. ll(1980) 1387. H. Kokodziej, M. Pajdowska, L. Sobczyk, J. Phys. E ll(1978) 752. P. Debye, Trans. Farad. Sot. 30(1934) 679. J.G. Powles, J. Chem. Phys. 21(1953) 633. E. Bauer, M. Magat, J. Phys. Radium 9(1938) 319. J.P. Poley, J. Appl. Sci. Res. B4(1955) 337. E.A.S. Cavell, M.A. Sheikh, J. C. S. Trans. Farad. II 71(1975) 474. D.W. Davidson, R.H. Cole, J. Chem. Phys. 19(1951) 1484. D.W. Davidson, Can. J. Chem. 39(1961) 571.
Advances in Molecular Relaxation and Interaction Processes, 22 (1982) 159-165 Elsevier Scientific Publishing Company, Amsterdam - Printed in The Netherlands
DIELECTRIC
M.
RELAXATION
Pajdowska
Institute
IN
PROPIONIC
ACID-TRI-N-BUTYLAMINE
SYSTEM
and L. Sobczyk of Chemistry,
University
of Wroclaw,
50-385
Wroclaw,
Poland (Received 7 September 1981) ABSTRACT The range
complex
electric
100 MHz-2GHz
-n-butylamine
permittivity
have been
systems
and viscosity
measured
of varying
composition.
relaxation
time and its distribution
especially
for 1:l species.
over
for the propionic Both,
indicate
the frequency acid-
the value
a remarkable
triof the
aggregation
INTRODUCTION Carboxylic techniques
acid-
both
amine
systems
in solution,
[l-71.
In such
systems
bonds,
leading
to the formation
position, binary The
the most
mixtures
studies
a strong
stable
of a proton
solvation
and
interaction
and
takes
presumably
bonds
self-solvation
and,
place
mixtures
via hydrogen com-
to be present
spectra
revealed
in particular,
equilibrium
In r6,71.
specific
the possible
and furthermore - creation
processes
various
1:l and 2:l adducts.
and infra-red
transfer
using
in binary
of miscellaneous
are also postulated
moments
of O-H.. .N hydrogen
features existence
studied
solvents
of complexes
being
3:l complexes
of dipole
have been
in inert
- due to
of free ions
111-151. The
aim of the present range
frequency
-n-butylamine information processes
related
(TBA)
work
mixtures of varying
on the structure which
processes.
for
could
Searches
is of
to study
composition.
of these
be ascribed
jumping
acid
remained,
over
the dispersion
(PrAH)
We hoped
liquids
and tri-
to gain
new
and on the relaxation
to the kinetics
for the dielectric
to the proton
E*(O)
propionic
response
of proton
which
might
so far, without
0378-4487/82/0000~000/$02.75 0 1982 Elsevier Scientific Publishing Company
transfer be directly
success.
160 EXPERIMENTAL The mixtures object
of carboxylic
for dielectric
and electric
work
the frequency method
range
of 100 MHz
and 5 sun depth
determination -terminal
which
connects
in our experiment
range
at 2 GHz
E’
+5%
for
been measured
of E*(W) have been
RESULTS
and
performed
For all systems
except
distribution
distinct
feature
we applied
cos h
-1
ratio
of
the liquid
line. The
allow
for the
of a two-portresults
the
obtained
+ 2% for E' and f 5% for E" E”
The viscosity
.
viscometer.
of
In addition
while
the liquidswas
the measurements
for PrAH + TBA complexes
in benzene.
whereas
in benzene
of the defined
relation
processes,
in the numerical
reflects
1 the behaviour
1
E’
far binary From
values
2 evaluated
mixtures
the plot
pure
to about
diagram
analysis:
time and
6
: TBA system
as an example
and the Fuoss-Kirkwood for respective
plot.
systems
~~ and 6 are given.
ratio
decrease
increases,
are long
of 17 against value
and
in the mean
Generally
the molar
fraction,
noticing
is, approximately,
relaxation
the relaxation
do not correlate
of n corresponds
3:l. It is worth
components
any
Hence
from monodispersivity.
are compared
show a striking
that the maximum
equal
of relaxation
of the 1:l PrAH
~~ as the acid/amine
it appears
evaluation the deviation
on the Cole-Cole and E"
a sig-
without
(1)
for a graphical which
in Table
of both
solutions
time is observed
=*ln.L!$tZ
The data obtained
cosity.
dilute
E’ ’
is illustrated In Table
the more
of the separation
E" max _
allows
In Fig.
ratio
capacitance
of 4-8 mm diameter
the theory
of the relaxation
the Fuoss-Kirkwood
coefficient,
times
wave
In
out over
AND DISCUSSION
nificant
time
k 7% for
by an Ostwald
the lumped
the end of a coaxial
levels
at 100 MHz
losses
reactivity.
has been carried
capacitor
by using
The confidence
a difficult
C161. In this method
shift and standing
of the impedance
network.
of chemical
glass to
represent
of high permittivity
- 2 GHz using
in our laboratory
of phase
amines
of E*(W)
is put into a cylindrical
measurements
which
because
and because
the measurement
developed
sample
studies
conductivity
the present
acids with
with
vis-
shown in Fig. 2
to the PrAH/TBA
that
the same.
the viscosity
161
A cos h-’
(0)
cmuc
I
E”
1
2-
l-
E” (b)
84-
Fig. 1. Cole-Cole (a) and Fuoss-Kirkwood acid TBA system.
(b) plots for 1:l propionic
In order to compare the relaxation times with the volume of defined species it is necessary to assume some theoretical model. From the literature data it follows that the best agreement between the effective molecular volume and that calculated from the dielectric relaxation time is obtained from the following relation [171:
T
u=
-2 nil
1 73 - 1o12
(2)
162
20 -
10 -
0+
I
Fig. 2. Viscosity PrAH - TBA system.
TABLE
System
- values v(MH2)
6:l
binary mixture
against
molar
fraction
of PrAH
1.0
for the
at 298 K E'
E"
162 250 520 1000 2000
7.44 6.47 5.33 4.47 4.42 3.78
4.0 4.16 3.08 1.92 1.51 0.91
100 162 250 520 1000 2000
9.10 8.22 6.33 5.82 3.92 4.15
6.33 6.20 4.06 3.35 2.70 1.11
100
162 250 520 1000 2000
9.45 8.76 6.94 6.59 4.38 4.50
5.37 5.84 4-69 3.95 2.99 1.29
100 162 250 520 1000 2000
10.59 9.79 7.15 6.73 4.35 4.32
4.37 6,03 7.23 S-25 3.68 1.63
100
111 binary mixture
3:l binary mixture
plotted
XA
1.
E’ and E"
2:l binary mixture
08
a2
System
1.6M PrAH in TBA
2.2M PrAH in TBA
1.6M complex in benzene
l.OM complex in benaene
v(MH.2)
E'
E"
100 165 250 600 1000 1600
3.79 3.52 3.32 3.00 3.12 2.90
0.85 0.69 0.93 0.53 0.44 0.49
100 165 250 600 1000 1600
4.52 3.98 3.69 3.25 3.29 3.40
1.58 1.38 1.28 0.65 0.54 0.71
100 165 250 730 1000 2000
6.75 5.86 5..87 4.29 4.03 3.64
1.11 1.46 1,88 1.85 1.54 1.36
100 165 250 730 1000 1666
5.00 4.74 4.48 3.91 3.64 3.33
0.66 0.68 0.94 1.33 l-05 1.01
163
TABLE
2.
Mean macroscopic relaxation time ~~ and the % Fuoss-Kirkwood parameter for PrAHsTBA systems. T=298
K
System
To'Ps
1:l 2:l 3:l 6:l 1.6M l.OM 2.2M 1.6M
binary mixture binary mixture binary mixture binary mixture complex in benzene complex in benzene PrAH in TBA PrAH in TBA
TABLE
3.
3150 1991 1600 760 398 282 2500 700
% 0.64 0.79 0.76 0.89 0.72 0.86 0.65 1.0
Molecular volumes of PrAH.TBA complexes VM compared with those calculated from dielectric relaxation times VD
cz31
System 1:l 2:l 3:l 6:l
binary binary binary binary
mixture mixture mixture mixture
528 659 790
?493 1712 994 1186
where Tu (from Powles) equals
2EO+ E, F--, ~~ being the macroscopic
relaxation time, while nU =O,l
n (from Debye)
0
where n is the macro-
scopic viscosity. Moreover, analysis of the literature data shows a distinctly positive deviation from equation (2) for polar associated liquids. In Table 3 the effective molecular volumes are compared with those calculated from dielectric relaxation time for various composition of liquids. Therefore, the liquids of 1:l ratio are, in terms of molecular volumes,. the most associated. The lowest % parameter occurs in conjunction with the highest relaxation time, thereby confirming the largest distribution of molecular volumes of reorientating species. In benzene solutions the PrAHtTBA system behaves normally but at a higher concentrations ho increases and % parameter decreases providing evidence of the aggregation process. The aggregation process is also observed in solutions .with excess TBA, where only 1:l complexes are formed., Considering the possible mechanisms of dielectric relaxation in our systems, the structural relaxation cannot be omitted L19, 20 1.
164
The
fact that, with
could
indioate
the ordered
excess PrAH, the
such a mechanism
structure
of
relaxation
since an
time decreases
excess
the liquid. However,
should disturb
at excess
of
amine which can be treated as a neutral solvent the observed relaxation time is again very long. Thus, one can suggest that there are relatively large molecular clusters with a life-time considerably exceeding the dielectric relaxation time. The distribution of relaxation times as a consequence of a statistical distribution of molecular masses seems to be in agreement with such an argument. The appearance of an expected additional relaxation process connected with proton motion is still not clear. Dielectric losses at the highest frequencies used in this work disappea.r but the ~~ value is considerably higher than ni which could indicate some faster process to be expected beyond the GHz frequency range. Table 4 contains collected data on e--n:
for the investigated
systems. TABLE 4. Molar ratio PrAH/TBA
EC0
1:l 2:l 3:l 6:l
4. 4.4 4.2 3.9
2 "D 2.0497 2.0598 2.0535 2.0135
2 ccc-n D 1.95 2.34 2.15 1.89
It is difficult to judge whether such remarkable increments can be entirely assigned to fairly well known effects like Poley absorption C201 and intramolecular motions giving rise to a change of dipole moment. The observed increment is close to those found for hydrogen bonded strongly associated liquids L21-231. Presumably, the main reason for the large E, - ni values in all systems of this type is the anomalous polarizability related to various protonic vibrations which are distinguished by .a high intensity in the absorption spectra.
REFERENCES 1 2 3 4
J.W. Smith, M.G. Victoria, J. Chem. Sot. 77(1968) 4474. DeLos F. DeTar, R.N. Novak, J. Am. Chem. Sot. 92(1970) 1361. G.M. Barrow, J. Am. Chem. Sot. 78(1956) 5802. M.F. Claydon, N. Sheppard, Chem. Comm. 43(1969).
165
5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23
S.L. Johnson, K.A. Rumon, J. Phys. Chem. 69(1965) 74. F. Kohler, E. Liebermann, G. Miksch, Ch. Keinz, J. Phys. Chem. 76(1976) 2764. M. Bobik, Abv. Mol. Relax. Proc. ll(1977) 191. M. Davies, L. Sobczyk, J. Chem. Sot. (1962) 3000 S.R. Gough, H.A. Price, J. Phys. Chem. 73(1969) 459. E. Jakusek, H. Koxodziej, L. Sobczyk, Acta Phys. Polon. 38A(1970) 57. E. Jakusek, M. Pajdowska, L. Sobczyk, Chem. Phys. 9(1975) 205. V.K. Venkatesen, C.V. Suryanarayna, J. Phys. Chem. 60(1956) 777. K.C. Molhotra, R.G. Sud, J. Inorg. Nucl. Chem. 38(1976) 775. J. Hurwic, J. Michalczyk, K. Pogorzelska, Roczniki Chemii 31 (1957) 265. P. Huyskens, N. Felix, A. Janssens, F. van den Broeck and F. Kapuku, J. Phys. Chem. ll(1980) 1387. H. Kokodziej, M. Pajdowska, L. Sobczyk, J. Phys. E ll(1978) 752. P. Debye, Trans. Farad. Sot. 30(1934) 679. J.G. Powles, J. Chem. Phys. 21(1953) 633. E. Bauer, M. Magat, J. Phys. Radium 9(1938) 319. J.P. Poley, J. Appl. Sci. Res. B4(1955) 337. E.A.S. Cavell, M.A. Sheikh, J. C. S. Trans. Farad. II 71(1975) 474. D.W. Davidson, R.H. Cole, J. Chem. Phys. 19(1951) 1484. D.W. Davidson, Can. J. Chem. 39(1961) 571.