- Email: [email protected]
Vibrational spectra of cis-stilbene
Journal of
MOLECULAR STRUCTURE Journal
of Molecular
Structure
349 (199.5)
29-32
Vibrational spectra of cis-stilbene. J.F. Arenas, I.L. To&n, J.C. Otero and J.I. Marcos. Department of Physical Chemistry, University of Malaga, E-2907 1-MQaga, Spain. Infrared and Raman spectra of cis-stilbene have been recorded and then interpreted with SQMFF methodology by using scale factors directly transferred from benzene and ethylene. The computed spectrum allowed for the complete assignment of in-plane vibrations of this molecule. 1. INTRODUCTION Vibrational spectrum of cis-stilbene has been the subject of very few studies while that of trans- isomer is rather well known [l-6]. A semiempirical calculation of the force field of cisstilbene was carried out by Warshel but his results were not compared with the experiment [3]. Anyway, he stressed the difficulty of analyzing the spectrum because of the steric hindrance of two hydrogens of benzene rings which are responsible for the non-planarity of the molecule. As a consequence, symmetry should be C2 instead of C2h and therefore every molecular vibrations should be i.r. and Raman active while trans-stilbene follows the mutual exclusion rule quite well [l-6]. That operative symmetry C2 has been confirmed by the i.r. and Raman results by Bree and Zwarich [7] because anomalous depolaritation ratios have been observed in the low frequency region. The respective bands correspond to out-of-plane vibrations which should be depolarized if the molecular point group were Czv. Because of the complexity of the spectrum, those authors have assigned only a few fundamentals which could be easily correlated with analogous modes of trans-stilbene. In this work, we report results of the force field calculation concerning in-plane vibrations of cis-stilbene with SQMFF methodology [8]. We think that this particular method is the most convenient one for molecules of moderate complexity where direct transfer of scale factors from related molecules is effective. In this case, scale factors have been transferred from benzene and ethylene. 2. RESULTS
AND DISCUSSION
All our quantum mechanical calculations were carried out by using a 3-21G basis. First of all, geometries of ethylene, benzene and cis-stilbene have been optimized and thereafter the i.r. respective force fields have been computed by analytical differentation in the equilibrium position. Internal coordinates have been chosen according to Pulay’s recomendations [9]. Finally, force constants of benzene and ethylene have been scaled in order to fit the respective experimental frequencies. Table 1 shows the calculated frequencies for in-plane vibrations of benzene which have been computed by introducing four scale factors (SET I), i.e. one for each internal coordinate. It is evident that agreement between computed and experimental data is good except for vibration 14, what made necessary to introduce an additional scale factor involving interaction 0022-2860/95/$09.50
0 1995 Elsevier
SSDI 0022-2860(95)08701-X
Science
B.V:
All rights reserved
30
force constans CC ortho-, meta- and para- (SET II). Table 2 shows final results for ethylene; in this case four scale factors involving diagonal force constants have been optimized too. Table 1 Observed and calculated wavenumbers (cm-l) for in-plane vibrations of benzene. Exp.['ol
cdC.1
2
3072
El,, 20 a,b Qg, 7 a&
3064 3057
3086 3072
Symmetry Alp
3056
calc.11
P.E.D.(%)
P.E.D.(%)
100 UK-H) . , 99 u(C-H)
3086 3072
100 u(C-H) 99 u&-H)
99 u(C-H) 100 u(C-H)
3056
99 u(C-H)
3047
100 u(C-H)
69 u(C-C), 24 &C-H)
1608
69 u(C-C), 23 &C-H)
1482
’
3056
3047
Qg, 8 a,b El,, 19 a,b
1599
1600
1482
1482
Azg,3
1350
1363
69 &C-H), 31 u(C-C) 100 &C-H)
1363
68 &C-H), 32 u(C-C) 100 &C-H)
B2u.14
1309
1215
54 &C-H), 48 u(C-C)
1307
84 u(C-C), 18 &C-H)
E2g, 9 0
1178
1182
80 &C-H), 20 u(C-C)
1185
81 &C-H), 21 u(C-C)
B2u, 15
1146
1129
84 u(C-C), 12 @C-H)
1167
84 S(C-H), 18 u(C-C)
El,,18
1037
1035
Blu, 12
1010
1000
69 u(C-C), 33 &C-H) 100 Gring
1036
69 u(C-C), 33 @C-H) 100 king
Alg,
993
994
990
606
611
100 U(C-C) 90 Gring
13
Blu,
0
1
E2g, 6 0
1000 611
100 U(C-C) 90 Gring
Table 2 Observed and calculated wavenumbers (cm-l) for in-plane vibrations of ethylene. Symmetry B2u Big Ag B3u
P.E.D. (%)
2) (C-H)
talc. 3110 3081
2) (C-H) 2) (C-H) 2) (C=C)
3039 3021 1628
96 v (C-H) 100 2) (C-H) 61 u (C=C), 38 2) (C-H)
6 (CH2)
1443
100 6 (CH2)
6 (CH2) r (CH2) r (CIW
1343
64 6 (CH2), 36 2) (C=C) 100 r (CH2) 100 r (CH2)
Exp.I”l 3105
Description
3086 3026
Ag B3u
3021 1630 1444
Ag
1342
Big l32u
1220 826
u (C-H)
1217 827
100 2) (C-H) 100 2) (C-H)
Scale factors have been transfered directly from benzene and ethylene to cis-stilbene. However, internal coordinates of the type ring-substituent (CX and CCC) have to be defined in this molecule; their respective scale factors have been fixed to be 0.8 with the exception of that involving u(C-X) which has been increased up to 0.91 to fit the experimental frequency of that vibration in the spectrum of trans-stilbene. Table 3 summarizes scale factors used to compute the theoretical spectrum of cis-isomer according to the C2 symmetry given by 3-21G basis.
31
Table 4 Calculated and observed in-plane vibrational frequencies (cm-l) of cis-stilbene. Mode A
IR 3079 m
3054 s
P.E.D. (%)
ModeB
P.E.D. (%)
3073
100 U&X-I)
3073
100 W-H)
3061 p, s
3060
98 U(C-H)
3060
99 W-H)
3049 dp, s
3047
98 u(C-H)
3047
99 u(C-H)
3040 84 U(C-H)e, 15 u(C-H) 3024 s
3030 dp, sh
3012 sh
3014 p, m
3036
87 u(C-H), 11 U(C-H)e
3036
98U(C-H)
3028
97 u(C-I-I)
3028
98 W-H)
3016
97 NC-H),
1629 p, vs
1656
56 u(C=C), 17 u(C-X)
1600s
1599 p, s
1615
64 u(C-C), 19 &C-H)
1617
66 u(C-C), 20 &C-H)
1576 m
1573 p, m
1588
66 u(C-C), 19 &C-H)
1591
69 u(C-C), 20 &C-H)
1498
58 &C-H), 34 u(C-C)
1452
55 &C-H), 33 u(C-C)
1402
69 &C-H), , 14 u(C-X)
1495 s 1490 s
1490 p, w
1494
63 &C-H), 33 u(C-C)
1449 s 1444s
1443 p, w
1406 m
1405 dp,vw
1336 VW 1333 ?, sh 1305 p, m 1234 p, m 1203 w
1448
60 &C-H), 34 u(C-C)
1339
84 &C-H)
1336
82 &C-H), 14 u(C-C)
1312
70 u(C-C), 14 NC-H),, 13 &C-H)
1295
85 u(C-C)
1244
46 u(C-C), 31 &C-H), 1203
33 u(C-X), 24 u(C-C), 15 &C-H)
1203 dp, m 1193 p, m
1191
82 &C-H), 17 u(C-C)
1190
81 &C-H), 18 u(C-C)
1180m
1182p,m
1173
78 &C-H), 21 u(C-C)
1172
80 &C-H), 19 u(C-H)
1156m
1149p, s
1la
23 u(C-C), 22 u(C-X), 18 &C_H)e,15 Gring
1078
57 u(C-C), 38 &C-H)
1082
54 W-C),
1074 s
416(C-H)
1029 s
1029 p, s
1026
70 u(C-C), 18 &C-H)
1027
66 u(C-C), 21 &C-H)
1001 w
1001 p, vs
998
43 Gring, 24 u(C-C)
995
62 Gring, 38 u(C-C)
619 w
619 dp, m
89 Gring
519 p, w
87 king 45 Gring, 14 GCCC
623
519 w
625 521
500
54 Gring, 11 u(C-X)
259
55 S(C-X), 14 ting
502m 261 p, m
248
28 ting,
20 GCCC,
20 &C-X)
32
Table 3 Optimized scale factors. Benzene Description Factor
Ethylene Description Factor 0.78 2) (C=C)
Benzene-Ethylene Description Factor 0.91 2) (C-X)
u (C-H)
o*83
U (C-C)
0.87
2) (C-H)
0.83
6 (C-X)
OS8
6 (C-H) 6 ring
0.78 0.76
6 (CH2) r (CH2)
0.77 0.77
6 (CCC)
O-8
2) (C-C)o,m,p
0.69
Generally speaking, the fit between experimental and computed frequencies is quite good. However, vibrations clearly involving either ring stretchings or ethylenic double bond stretching (1700 - 1500 cm-l region) are computed systematically in excess, what suggests that 3-21G underestimates molecular electronic delocalization. On the other hand, four fundamentals are calculated at frequencies higher than 1400 cm-l corresponding to the vibrations 19ab of benzene, which can be observed split in the infrared spectrum according to the symmetry C2. Likewise, vibration G(CHe) B, is easily assigned to the Raman depolarized band recorded at 1405 cm-l while the respective mode of symmetry A participates in several fundamentals of the 1300 cm-1 region. These vibrations exhibit two significant differences with respect to the trans- isomer. First, in cis-stilbene it is difficult to assign mode G(CHe) A to any single band while in trans-stilbene it is quite straightforward to identify it; secondly, separation between symmetric and antisymmetric modes is significantly higher in the spectrum of cis-stilbene what suggests a stronger coupling between modes when both CHe bonds are in cis position. Finally, it is to be stressed the excelent agreement between experimental and computed frequencies as well as the optimum prediction of the order of appearing of the fundamentals, as can be seen by correlating the observed polarized Raman bands with the calculated A fundamentals. Therefore, the assumed hypothesis of the transferibility of scale factors between these molecules is sufficiently proved.
Acknowledgement The authors would like to express their gratitude to the CICYT for the financial support for this work through Project # PB90/0806.
REFERENCES 1. G. Baranovic, Z. Meic, H. Gusten, J. Mink and G. Keresztury, J. Phys. Chem., 94 (1990) 2833. 2. K. Palm& Spectrochim. Acta, 44A (1988) 341. 3. A. Warshel, J. Chem. Phys., 62 (1975) 214. 4. Z. Meic y H. Gtisten, Spectrochim. Acta, 34A (1978) 101. 5. C. Pecile y B. Lunelli, Can. J. Chem. 47 (1969) 243. 6. Z. Meic, B. Baranovic y D. Skare, J. Mol. Struct., 141 (1986) 375. 7. A. Bree y R. Zwarich, J. Mol. Struct. 75 (1981) 213. 8. X. Zhon, G. Fogarasi, R. Liu, P. Pulay, Spectrochim. Acta, 49A (1993) 1499. 9. P. Pulay y G. Fogarasi, J. Am. Chem. Sot., 101 (1979) 2550. 10. G.Varsanyi, ” Vibrational spectra of benzene derivatives ‘0 Academic Press, New York 1969. 11. P. Pulay, G. Fogarasi, G. Pongor, J. E. Boggs y A. Vargha, J. Am. Chem. Sot., 105 (1983) 7073.
MOLECULAR STRUCTURE Journal
of Molecular
Structure
349 (199.5)
29-32
Vibrational spectra of cis-stilbene. J.F. Arenas, I.L. To&n, J.C. Otero and J.I. Marcos. Department of Physical Chemistry, University of Malaga, E-2907 1-MQaga, Spain. Infrared and Raman spectra of cis-stilbene have been recorded and then interpreted with SQMFF methodology by using scale factors directly transferred from benzene and ethylene. The computed spectrum allowed for the complete assignment of in-plane vibrations of this molecule. 1. INTRODUCTION Vibrational spectrum of cis-stilbene has been the subject of very few studies while that of trans- isomer is rather well known [l-6]. A semiempirical calculation of the force field of cisstilbene was carried out by Warshel but his results were not compared with the experiment [3]. Anyway, he stressed the difficulty of analyzing the spectrum because of the steric hindrance of two hydrogens of benzene rings which are responsible for the non-planarity of the molecule. As a consequence, symmetry should be C2 instead of C2h and therefore every molecular vibrations should be i.r. and Raman active while trans-stilbene follows the mutual exclusion rule quite well [l-6]. That operative symmetry C2 has been confirmed by the i.r. and Raman results by Bree and Zwarich [7] because anomalous depolaritation ratios have been observed in the low frequency region. The respective bands correspond to out-of-plane vibrations which should be depolarized if the molecular point group were Czv. Because of the complexity of the spectrum, those authors have assigned only a few fundamentals which could be easily correlated with analogous modes of trans-stilbene. In this work, we report results of the force field calculation concerning in-plane vibrations of cis-stilbene with SQMFF methodology [8]. We think that this particular method is the most convenient one for molecules of moderate complexity where direct transfer of scale factors from related molecules is effective. In this case, scale factors have been transferred from benzene and ethylene. 2. RESULTS
AND DISCUSSION
All our quantum mechanical calculations were carried out by using a 3-21G basis. First of all, geometries of ethylene, benzene and cis-stilbene have been optimized and thereafter the i.r. respective force fields have been computed by analytical differentation in the equilibrium position. Internal coordinates have been chosen according to Pulay’s recomendations [9]. Finally, force constants of benzene and ethylene have been scaled in order to fit the respective experimental frequencies. Table 1 shows the calculated frequencies for in-plane vibrations of benzene which have been computed by introducing four scale factors (SET I), i.e. one for each internal coordinate. It is evident that agreement between computed and experimental data is good except for vibration 14, what made necessary to introduce an additional scale factor involving interaction 0022-2860/95/$09.50
0 1995 Elsevier
SSDI 0022-2860(95)08701-X
Science
B.V:
All rights reserved
30
force constans CC ortho-, meta- and para- (SET II). Table 2 shows final results for ethylene; in this case four scale factors involving diagonal force constants have been optimized too. Table 1 Observed and calculated wavenumbers (cm-l) for in-plane vibrations of benzene. Exp.['ol
cdC.1
2
3072
El,, 20 a,b Qg, 7 a&
3064 3057
3086 3072
Symmetry Alp
3056
calc.11
P.E.D.(%)
P.E.D.(%)
100 UK-H) . , 99 u(C-H)
3086 3072
100 u(C-H) 99 u&-H)
99 u(C-H) 100 u(C-H)
3056
99 u(C-H)
3047
100 u(C-H)
69 u(C-C), 24 &C-H)
1608
69 u(C-C), 23 &C-H)
1482
’
3056
3047
Qg, 8 a,b El,, 19 a,b
1599
1600
1482
1482
Azg,3
1350
1363
69 &C-H), 31 u(C-C) 100 &C-H)
1363
68 &C-H), 32 u(C-C) 100 &C-H)
B2u.14
1309
1215
54 &C-H), 48 u(C-C)
1307
84 u(C-C), 18 &C-H)
E2g, 9 0
1178
1182
80 &C-H), 20 u(C-C)
1185
81 &C-H), 21 u(C-C)
B2u, 15
1146
1129
84 u(C-C), 12 @C-H)
1167
84 S(C-H), 18 u(C-C)
El,,18
1037
1035
Blu, 12
1010
1000
69 u(C-C), 33 &C-H) 100 Gring
1036
69 u(C-C), 33 @C-H) 100 king
Alg,
993
994
990
606
611
100 U(C-C) 90 Gring
13
Blu,
0
1
E2g, 6 0
1000 611
100 U(C-C) 90 Gring
Table 2 Observed and calculated wavenumbers (cm-l) for in-plane vibrations of ethylene. Symmetry B2u Big Ag B3u
P.E.D. (%)
2) (C-H)
talc. 3110 3081
2) (C-H) 2) (C-H) 2) (C=C)
3039 3021 1628
96 v (C-H) 100 2) (C-H) 61 u (C=C), 38 2) (C-H)
6 (CH2)
1443
100 6 (CH2)
6 (CH2) r (CH2) r (CIW
1343
64 6 (CH2), 36 2) (C=C) 100 r (CH2) 100 r (CH2)
Exp.I”l 3105
Description
3086 3026
Ag B3u
3021 1630 1444
Ag
1342
Big l32u
1220 826
u (C-H)
1217 827
100 2) (C-H) 100 2) (C-H)
Scale factors have been transfered directly from benzene and ethylene to cis-stilbene. However, internal coordinates of the type ring-substituent (CX and CCC) have to be defined in this molecule; their respective scale factors have been fixed to be 0.8 with the exception of that involving u(C-X) which has been increased up to 0.91 to fit the experimental frequency of that vibration in the spectrum of trans-stilbene. Table 3 summarizes scale factors used to compute the theoretical spectrum of cis-isomer according to the C2 symmetry given by 3-21G basis.
31
Table 4 Calculated and observed in-plane vibrational frequencies (cm-l) of cis-stilbene. Mode A
IR 3079 m
3054 s
P.E.D. (%)
ModeB
P.E.D. (%)
3073
100 U&X-I)
3073
100 W-H)
3061 p, s
3060
98 U(C-H)
3060
99 W-H)
3049 dp, s
3047
98 u(C-H)
3047
99 u(C-H)
3040 84 U(C-H)e, 15 u(C-H) 3024 s
3030 dp, sh
3012 sh
3014 p, m
3036
87 u(C-H), 11 U(C-H)e
3036
98U(C-H)
3028
97 u(C-I-I)
3028
98 W-H)
3016
97 NC-H),
1629 p, vs
1656
56 u(C=C), 17 u(C-X)
1600s
1599 p, s
1615
64 u(C-C), 19 &C-H)
1617
66 u(C-C), 20 &C-H)
1576 m
1573 p, m
1588
66 u(C-C), 19 &C-H)
1591
69 u(C-C), 20 &C-H)
1498
58 &C-H), 34 u(C-C)
1452
55 &C-H), 33 u(C-C)
1402
69 &C-H), , 14 u(C-X)
1495 s 1490 s
1490 p, w
1494
63 &C-H), 33 u(C-C)
1449 s 1444s
1443 p, w
1406 m
1405 dp,vw
1336 VW 1333 ?, sh 1305 p, m 1234 p, m 1203 w
1448
60 &C-H), 34 u(C-C)
1339
84 &C-H)
1336
82 &C-H), 14 u(C-C)
1312
70 u(C-C), 14 NC-H),, 13 &C-H)
1295
85 u(C-C)
1244
46 u(C-C), 31 &C-H), 1203
33 u(C-X), 24 u(C-C), 15 &C-H)
1203 dp, m 1193 p, m
1191
82 &C-H), 17 u(C-C)
1190
81 &C-H), 18 u(C-C)
1180m
1182p,m
1173
78 &C-H), 21 u(C-C)
1172
80 &C-H), 19 u(C-H)
1156m
1149p, s
1la
23 u(C-C), 22 u(C-X), 18 &C_H)e,15 Gring
1078
57 u(C-C), 38 &C-H)
1082
54 W-C),
1074 s
416(C-H)
1029 s
1029 p, s
1026
70 u(C-C), 18 &C-H)
1027
66 u(C-C), 21 &C-H)
1001 w
1001 p, vs
998
43 Gring, 24 u(C-C)
995
62 Gring, 38 u(C-C)
619 w
619 dp, m
89 Gring
519 p, w
87 king 45 Gring, 14 GCCC
623
519 w
625 521
500
54 Gring, 11 u(C-X)
259
55 S(C-X), 14 ting
502m 261 p, m
248
28 ting,
20 GCCC,
20 &C-X)
32
Table 3 Optimized scale factors. Benzene Description Factor
Ethylene Description Factor 0.78 2) (C=C)
Benzene-Ethylene Description Factor 0.91 2) (C-X)
u (C-H)
o*83
U (C-C)
0.87
2) (C-H)
0.83
6 (C-X)
OS8
6 (C-H) 6 ring
0.78 0.76
6 (CH2) r (CH2)
0.77 0.77
6 (CCC)
O-8
2) (C-C)o,m,p
0.69
Generally speaking, the fit between experimental and computed frequencies is quite good. However, vibrations clearly involving either ring stretchings or ethylenic double bond stretching (1700 - 1500 cm-l region) are computed systematically in excess, what suggests that 3-21G underestimates molecular electronic delocalization. On the other hand, four fundamentals are calculated at frequencies higher than 1400 cm-l corresponding to the vibrations 19ab of benzene, which can be observed split in the infrared spectrum according to the symmetry C2. Likewise, vibration G(CHe) B, is easily assigned to the Raman depolarized band recorded at 1405 cm-l while the respective mode of symmetry A participates in several fundamentals of the 1300 cm-1 region. These vibrations exhibit two significant differences with respect to the trans- isomer. First, in cis-stilbene it is difficult to assign mode G(CHe) A to any single band while in trans-stilbene it is quite straightforward to identify it; secondly, separation between symmetric and antisymmetric modes is significantly higher in the spectrum of cis-stilbene what suggests a stronger coupling between modes when both CHe bonds are in cis position. Finally, it is to be stressed the excelent agreement between experimental and computed frequencies as well as the optimum prediction of the order of appearing of the fundamentals, as can be seen by correlating the observed polarized Raman bands with the calculated A fundamentals. Therefore, the assumed hypothesis of the transferibility of scale factors between these molecules is sufficiently proved.
Acknowledgement The authors would like to express their gratitude to the CICYT for the financial support for this work through Project # PB90/0806.
REFERENCES 1. G. Baranovic, Z. Meic, H. Gusten, J. Mink and G. Keresztury, J. Phys. Chem., 94 (1990) 2833. 2. K. Palm& Spectrochim. Acta, 44A (1988) 341. 3. A. Warshel, J. Chem. Phys., 62 (1975) 214. 4. Z. Meic y H. Gtisten, Spectrochim. Acta, 34A (1978) 101. 5. C. Pecile y B. Lunelli, Can. J. Chem. 47 (1969) 243. 6. Z. Meic, B. Baranovic y D. Skare, J. Mol. Struct., 141 (1986) 375. 7. A. Bree y R. Zwarich, J. Mol. Struct. 75 (1981) 213. 8. X. Zhon, G. Fogarasi, R. Liu, P. Pulay, Spectrochim. Acta, 49A (1993) 1499. 9. P. Pulay y G. Fogarasi, J. Am. Chem. Sot., 101 (1979) 2550. 10. G.Varsanyi, ” Vibrational spectra of benzene derivatives ‘0 Academic Press, New York 1969. 11. P. Pulay, G. Fogarasi, G. Pongor, J. E. Boggs y A. Vargha, J. Am. Chem. Sot., 105 (1983) 7073.