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The infrared dielectric function of liquid triethylamine
ELSEVIER
Journal of Molecular
THE INFRARED
Liquids67
(1995) 21 l-216
DIELECTRIC FUNCTION TRIETHYLAMINE*
OF LIQUID
J. P. Hawranek and W. Wrzeszcz
institute of Chemistry Uniwersity of Wrociaw XI-383 WROCLAW, F. Joliot-Curie 14, Poland
Abstract The spectra of both components
of the complex
refractive
index and of the
complex electric permittivity for liquid biethylamine at 298 K were estimated from thin film transmission spectra in the 3200 - 650 cm-’ range. From these data, the molar vibrational polarization was determined m selected regions, and their contribution to the total value for the studied molecule was discussed.
The spectra of both components
of the complex
polarizability of the molecule in liquid phase were also obtained in the studied region and discussed.
Introduction Triethylamine spectroscopic
(TEA) is an important and frequently
[1,2 and references
used proton
acceptor
in
cited therein] and dielectric [3] studies of hydrogen
bonded systems. It has found also a variety of numerous
other applications
sciences and technology. Despite of that, the basic spectroscopic
in chemical
data and physico-chemical
properties of neat liquid TEA are surprisingly poorly explored. The aim of this work was to obtain information on dielectric properties of liquid TEA in the Mid-Intiared
* This work is dedicated to Professor P. Huyskens. 0167-7322/95/$09.50 0 1995 Elwier SSDI 0167.7322 (95) 008764
Science B.V. All rights reserved
region.
212
Experimental and data processing In a previous work the thin film transmission
spectra in the 3200 - 650 cm-’
region and the integrated intensities were obtained experimentally and discussed [4]. In this work we extend the study by determining the spectra of both components
of the complex
refractive index: ri(o)=n(u)+ik(u)
using the procedure
(1)
described in more detail elsewhere [5] Subsequently, the spectra of
both components of the complex electric permittivity:
Z(0) = &‘( 0) + i&“( u)
(2)
were obtained in the entire studied region following Maxwell’s relations. All results were obtained at controlled temperature
of 298 K; u denotes wavenumbers
[cm-‘] throughout
this work.
Results and discussion Ihe dielectric jhction
In Fig.
1 the
i(u)
spectrum
3200 - 2400 cm-’ region
is shown.
stretching vibrations of the
-CH,
of the
studied
In this region,
and
> CH,
liquid triethylamine
in the
the bands corresponding
to the
groups are dominating. In general, 14
bands were identified in this region, out of which 8 were quantitatively described [4] in terms of band positions, half-widths and integrated intensities In particular, asymmetric stretching
the
2971.0 cm-’ and
modes of the -CH,
2933.4 cm-’ bands
correspond
and > CH, groups, respectively,
2873.3 cm-’ and 2804.9 cm-’ bands are related to the corresponding
to the while the
symmetric stretching
vibrations of these groups [4]. In Fig. 2 the second prominent TEA is presented.
In this region
absorption region
absorption
bands
(2400 - 650 cm-‘) of liquid
corresponding
to the numerous
deformation modes of the -CH, and > CH, groups occur, as well as of the C-C and C-N stretching modes. In this region 36 bands were quantitatively described [4].
213
0.0 3200
E”(V) 3100
3000
2300
2700
2800
2400
2500
2600
v
WI
Fig. 1. The i(u) spectrum of liquid triethylamine in the 3200 - 2400 cm“ region.
“1
0.30-
025.
1
TRIETHYLAMINE
020. 0.15. 0.10. 0.05. O.Oh 2400
P(V) 22On
2000
IS00
1600
1400
1200
1000
BOO vlcd
Fig. 2. The g(u) spectrum of liquid triethylamine in the 2400 - 650 cm“ retion.
214
As can be seen, several bands of TEA are intrinsically of medium strength, with the strongest asym-
v,(CH,)
at 2971 .O cm-’ showing EE
at the level of 0.1-0.2 as concerns
above 0.4; several other bands are
&;a
The molar vibrational polarization.
Using the dielectric function
i(v),
the molar vibrational polarization
determined for selected groups of vibrations (corresponding
P”
was
to related spectral ranges), with
the use of the procedure described elsewhere [6]. Because of the considerable overlapping of bands and difficulties with their exact assignement,
we did not attempt at this stage to
obtain values for particular modes. The results are presented in Table 1. Table 1. Molar vibrational polarization of liquid triethylamine in the M d-IR T=298 K. P Mb
Range [ cm-’]
AS’. 10’
[ cm3 .mole-’ ]
3200 - 2400
6.98 + 0.26
0.250 + 0.010
2400 - 650
24.66 k 0.30
0.869 If:0.010 1.119f0.010
CP”” 3200-
650
The values of P*
31.63 kO.18
1.131 +0.015
were calculated assuming a density value of 0.7235 g . cm-’ for
TEA at 298 K, which amounts to a molar volume of 139.86 cm-' .mole-' As can be seen, the overall value of the vibrational polarization of TEA related to modes exhibiting bands in the Mid-IR is not too impressive and amounts to only 1.12 cm.mole-’
It is interesting to
note, that the value related roughly to the CH stretching vibrations (i.e. corresponding the
3200 - 2400 cm-’ range)
is much smaller than that one corresponding
to
to the
deformation modes. The wavenumber dependent complex molecular polarizability
From 2(v) , the complex molecular polarizability function, with the assumption of the Lorentz internal field:
ir( v) , was calculated
215
&(o)=a’(u)+ia”(U)
Using the Clausius-Mossotti
(3)
equation in the form [7]:
$0)-l
A4
i(v)+2
d
--=
4
_tiA&(V)
(4)
3
one can obtain, by separation of the real and imaginary parts of ix(v) :
3 a’(v) = 4d,
&‘2(D)+&“*(LJ)+&‘(u)-22 [&‘(D)+2]t+&“*(u)
&‘I(0) 9 a”(U) = 4ldv, [&I(D)+2]* +P(v)
(5)
m
(6)
VI
were N, denotes Avogadro’s number and V,,, - the molar volume of the liquid. The shape of this spectrum for liquid TEA in the entire
studied
region is shown in Fig.3,
showing the relative intensities of all bands in a common scale.
a”‘@9 2000
1500
loo0
&m-l]
Fig. 3. The spectrum of the complex polarizability of liquid triethylamine, in units of
[ 1O-*’cm’ I molecule ]
216
At the high wavenumber limit of the spectrum, the level of a’(u) electronic polarizability of the molecule. With decreasing
is predetermined
wavenumbers,
by the
the vibrational
contributions become visible. The molar refraction
With the density value of 0.7235 g. cm-’ and the refractive index of 1.39697 (both at 298 K) the molar refraction of TEA amounts to 33.68 cm .moZe-’
Conclusion The total distortion polarization study equals to 34.80 cm.moK’
of the studied triethylamine
determined
in this
Thus, the vibrational contribution, stemming from modes
in the 3200 - 650 cm-’ range is very small, amounting to only ca. 3.2 %. This figure will obviously increase after the completion of the study with FIR data. This paper has been presented on the Molecular Spectroscopy
Conference [S]
References R. Kramer and G. Zundel, J. Chem. Sot. Faraday TransZZ 86 (1990) 301. S.E. Odinokov, V.P. Glazunov, A.A. Nabiullin, .JChem.Soc. Faraday Trans. II 80 (1984) 899. H. Ratajczak and L. Sobczyk, J. Chem. Phys. 50 (1969) 556; Bull. Acad. Pol. Sci., ser. xi chim. 18 (1970) 93. J.P. Hawranek, W. Wrzeszcz, and G.C Wycisk, Bull. Pal. Acad. SCI. (Chem.), 42 (1994) 141. J.P. Hawranek, W. Wrzeszcz and M. A. Czamecki, J. Mol. Strut.,
321 (1994) 13 1.
J.P. Hawranek and M. A. Czamecki, Chem. Phys. Letters, 151 (1988) 340. C.J.F. Bottcher and P. Bordewijk, Theov of Electric Polarization, Vol. II, Dielectrics in time-dependent fields, Ch. XII, Elsevier, Amsterdam 1978. J.P. Hawranek and W. Wrzeszcz, II-nd National Conference on Molecular Spectroscopy with International Participation, Wroclaw 27-30. IX. 1993. Book of Abstracts, P-22.
Journal of Molecular
THE INFRARED
Liquids67
(1995) 21 l-216
DIELECTRIC FUNCTION TRIETHYLAMINE*
OF LIQUID
J. P. Hawranek and W. Wrzeszcz
institute of Chemistry Uniwersity of Wrociaw XI-383 WROCLAW, F. Joliot-Curie 14, Poland
Abstract The spectra of both components
of the complex
refractive
index and of the
complex electric permittivity for liquid biethylamine at 298 K were estimated from thin film transmission spectra in the 3200 - 650 cm-’ range. From these data, the molar vibrational polarization was determined m selected regions, and their contribution to the total value for the studied molecule was discussed.
The spectra of both components
of the complex
polarizability of the molecule in liquid phase were also obtained in the studied region and discussed.
Introduction Triethylamine spectroscopic
(TEA) is an important and frequently
[1,2 and references
used proton
acceptor
in
cited therein] and dielectric [3] studies of hydrogen
bonded systems. It has found also a variety of numerous
other applications
sciences and technology. Despite of that, the basic spectroscopic
in chemical
data and physico-chemical
properties of neat liquid TEA are surprisingly poorly explored. The aim of this work was to obtain information on dielectric properties of liquid TEA in the Mid-Intiared
* This work is dedicated to Professor P. Huyskens. 0167-7322/95/$09.50 0 1995 Elwier SSDI 0167.7322 (95) 008764
Science B.V. All rights reserved
region.
212
Experimental and data processing In a previous work the thin film transmission
spectra in the 3200 - 650 cm-’
region and the integrated intensities were obtained experimentally and discussed [4]. In this work we extend the study by determining the spectra of both components
of the complex
refractive index: ri(o)=n(u)+ik(u)
using the procedure
(1)
described in more detail elsewhere [5] Subsequently, the spectra of
both components of the complex electric permittivity:
Z(0) = &‘( 0) + i&“( u)
(2)
were obtained in the entire studied region following Maxwell’s relations. All results were obtained at controlled temperature
of 298 K; u denotes wavenumbers
[cm-‘] throughout
this work.
Results and discussion Ihe dielectric jhction
In Fig.
1 the
i(u)
spectrum
3200 - 2400 cm-’ region
is shown.
stretching vibrations of the
-CH,
of the
studied
In this region,
and
> CH,
liquid triethylamine
in the
the bands corresponding
to the
groups are dominating. In general, 14
bands were identified in this region, out of which 8 were quantitatively described [4] in terms of band positions, half-widths and integrated intensities In particular, asymmetric stretching
the
2971.0 cm-’ and
modes of the -CH,
2933.4 cm-’ bands
correspond
and > CH, groups, respectively,
2873.3 cm-’ and 2804.9 cm-’ bands are related to the corresponding
to the while the
symmetric stretching
vibrations of these groups [4]. In Fig. 2 the second prominent TEA is presented.
In this region
absorption region
absorption
bands
(2400 - 650 cm-‘) of liquid
corresponding
to the numerous
deformation modes of the -CH, and > CH, groups occur, as well as of the C-C and C-N stretching modes. In this region 36 bands were quantitatively described [4].
213
0.0 3200
E”(V) 3100
3000
2300
2700
2800
2400
2500
2600
v
WI
Fig. 1. The i(u) spectrum of liquid triethylamine in the 3200 - 2400 cm“ region.
“1
0.30-
025.
1
TRIETHYLAMINE
020. 0.15. 0.10. 0.05. O.Oh 2400
P(V) 22On
2000
IS00
1600
1400
1200
1000
BOO vlcd
Fig. 2. The g(u) spectrum of liquid triethylamine in the 2400 - 650 cm“ retion.
214
As can be seen, several bands of TEA are intrinsically of medium strength, with the strongest asym-
v,(CH,)
at 2971 .O cm-’ showing EE
at the level of 0.1-0.2 as concerns
above 0.4; several other bands are
&;a
The molar vibrational polarization.
Using the dielectric function
i(v),
the molar vibrational polarization
determined for selected groups of vibrations (corresponding
P”
was
to related spectral ranges), with
the use of the procedure described elsewhere [6]. Because of the considerable overlapping of bands and difficulties with their exact assignement,
we did not attempt at this stage to
obtain values for particular modes. The results are presented in Table 1. Table 1. Molar vibrational polarization of liquid triethylamine in the M d-IR T=298 K. P Mb
Range [ cm-’]
AS’. 10’
[ cm3 .mole-’ ]
3200 - 2400
6.98 + 0.26
0.250 + 0.010
2400 - 650
24.66 k 0.30
0.869 If:0.010 1.119f0.010
CP”” 3200-
650
The values of P*
31.63 kO.18
1.131 +0.015
were calculated assuming a density value of 0.7235 g . cm-’ for
TEA at 298 K, which amounts to a molar volume of 139.86 cm-' .mole-' As can be seen, the overall value of the vibrational polarization of TEA related to modes exhibiting bands in the Mid-IR is not too impressive and amounts to only 1.12 cm.mole-’
It is interesting to
note, that the value related roughly to the CH stretching vibrations (i.e. corresponding the
3200 - 2400 cm-’ range)
is much smaller than that one corresponding
to
to the
deformation modes. The wavenumber dependent complex molecular polarizability
From 2(v) , the complex molecular polarizability function, with the assumption of the Lorentz internal field:
ir( v) , was calculated
215
&(o)=a’(u)+ia”(U)
Using the Clausius-Mossotti
(3)
equation in the form [7]:
$0)-l
A4
i(v)+2
d
--=
4
_tiA&(V)
(4)
3
one can obtain, by separation of the real and imaginary parts of ix(v) :
3 a’(v) = 4d,
&‘2(D)+&“*(LJ)+&‘(u)-22 [&‘(D)+2]t+&“*(u)
&‘I(0) 9 a”(U) = 4ldv, [&I(D)+2]* +P(v)
(5)
m
(6)
VI
were N, denotes Avogadro’s number and V,,, - the molar volume of the liquid. The shape of this spectrum for liquid TEA in the entire
studied
region is shown in Fig.3,
showing the relative intensities of all bands in a common scale.
a”‘@9 2000
1500
loo0
&m-l]
Fig. 3. The spectrum of the complex polarizability of liquid triethylamine, in units of
[ 1O-*’cm’ I molecule ]
216
At the high wavenumber limit of the spectrum, the level of a’(u) electronic polarizability of the molecule. With decreasing
is predetermined
wavenumbers,
by the
the vibrational
contributions become visible. The molar refraction
With the density value of 0.7235 g. cm-’ and the refractive index of 1.39697 (both at 298 K) the molar refraction of TEA amounts to 33.68 cm .moZe-’
Conclusion The total distortion polarization study equals to 34.80 cm.moK’
of the studied triethylamine
determined
in this
Thus, the vibrational contribution, stemming from modes
in the 3200 - 650 cm-’ range is very small, amounting to only ca. 3.2 %. This figure will obviously increase after the completion of the study with FIR data. This paper has been presented on the Molecular Spectroscopy
Conference [S]
References R. Kramer and G. Zundel, J. Chem. Sot. Faraday TransZZ 86 (1990) 301. S.E. Odinokov, V.P. Glazunov, A.A. Nabiullin, .JChem.Soc. Faraday Trans. II 80 (1984) 899. H. Ratajczak and L. Sobczyk, J. Chem. Phys. 50 (1969) 556; Bull. Acad. Pol. Sci., ser. xi chim. 18 (1970) 93. J.P. Hawranek, W. Wrzeszcz, and G.C Wycisk, Bull. Pal. Acad. SCI. (Chem.), 42 (1994) 141. J.P. Hawranek, W. Wrzeszcz and M. A. Czamecki, J. Mol. Strut.,
321 (1994) 13 1.
J.P. Hawranek and M. A. Czamecki, Chem. Phys. Letters, 151 (1988) 340. C.J.F. Bottcher and P. Bordewijk, Theov of Electric Polarization, Vol. II, Dielectrics in time-dependent fields, Ch. XII, Elsevier, Amsterdam 1978. J.P. Hawranek and W. Wrzeszcz, II-nd National Conference on Molecular Spectroscopy with International Participation, Wroclaw 27-30. IX. 1993. Book of Abstracts, P-22.