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Vibrational spectra of centrosymmetric molecules
JoumaL Ekvlgr
of golecuZar Sfrrrcrurz, 131(198S) Sciace Publishers B-V_, Ams+dam
ViBRATIoNAL
L%k’JXA
OF CENTFkOSYYM&ETRIG MOLECEXZS
Part HI_ meso-3,4KGbromohexane
i-3. A
..245-262 - F’rinted in The Netherlands
and meso-2,3,4&tekahromohexane
CROWDER
Depmfment (l&&iv&d
of Chemisfry.
WestT&us State
University.
Canyon,
Texas
79016
(U-S_&)
24 May 19Fs)
Liquid and s&id-state infra& and liquid-state Raman spectra were obtained for meso3,4dibromohexane and meao-2.3.4.5-tetrahromohesane‘I%e spectra show tie dihromotieme to erist as-2wo or more ccnformatio~_ in the neat liquid, including one that is cenizosymmeiric and one. thet is not centrosynunetric. The solid erkts only as one of tie This confc0xnation probably has all six two posible centrosymmetric conformstions. ~arbonx coplanar. The fetrahromc;7exa.ue ia a solid at rc,om temperatare and there is c&y one conformer present. The hck of coincidence of F&man and infrared bands show that conformer tomhave a center of symmetryNo additional conformers were found in dilute carbon disumde solution_ INTRODUCTION
It has recently been shown that meso-2,3~ibro~:o-l,~chloIulbutane [1] and meso-1,2,3,4-tetmbromobuk~e [Z] exist in the crystalline state in the centrosymmelzkal conformation with all carbolls %nd primary halogen coplanar. It has also been shown that meso-2,3d&romobut’ane crystalhzes in the centro~~mmetrical conformation [3] _ Vibrational spectra have now been obtained for meso-3,kIibromohexane and meso-2,3,4,S&rabromohexzme in order to compare the coizformational behavior of these compounds with the skructurahy similar compounds already studied_ EXPERIMEN’I’AL
meso-3,4-Dibromohexae was prepared by the stereospecific bromination of tiuns-313exene with CC& as solvent. The product was distilled and then redistilled, both times at reduced pressure. A fi-action boiling at 83-84”C/15 Torr each time was collected and. used. The spectra before and after the second distillation showed no differences, and gas chromatqraphic ana@rsis indicated the presence of only one compound_ meso-2,3,4.5-Telxabromohexane was prepared,_:in the same way as the dibromohexane, by bromination of tians,trans2,!Chexadiene. The productwas a white solid, wrich. was r~rystalhzed from CRC13~(mp. 180” C). 0022-2~60/35/~03.30
Q 1985
Elsevier
Science
Publishers
B-V_
246 were obtained with a Reclunan R-12 s_pectkphotometer m-1 FTIR spectrometer and Reman spectra vrere obtained &h a Beckman Model 700 spectrometer equipped with a Coherent R-ad$ai tioa Labs CR-2 Arron ion laser. The 488.0 nm line Y&SE&_ hhred
spectra
or a Nicolet
RESULTS
AND
DISCUSSION
Infmredspectraofmeso -3&dibromohex& (DBH) zire shown in Figs-l -and 2, and the Raman spectrun of the liquid is shown in Fig.3. The observed bands are listed ic Table 1. The C-Br &ret&kg frequencies of alI possible conformers of DRX would lie in the 500-700 cm-’ region. Liquid-state lR and Raman spectra show bands in this region at 670, 617, 559, 527 (IR) and at 673, 648, 625, and 533 cm-’ (R). Observation of this many bands indicates the presence of more than one conformation. In an effort to isolate bands due to one conformation, tied spectra were obtained for the solid, which was formed by cooling a liquid Glm to ca 80 K. The solidstate TR spectrum (Fig. 2) shows only the.550 cm-’ band in the C-Br stretch region. The z&appearance of the o+her bands in this region verifies the presence of rotational isomers_ Although there are a few coincidences of solid-state IR and liquid-state Raman bands, most of the solid-state lR bends do not have Ramen counterparts, including nearly all the strong IR. bands. It can therefore be concluded that the conformer preseu tinthesolid
I 1600
1400
1200
loo0
J
800
000
400
m-1
Fig_ 1. Partial
liquid&ate IR spectium of me60-3.4-dilxomoherze
at r&m tempmature.
247
%T
l-
1600
1200 CM-’
1400
Fig. 2. Partial solid-state
Fig_ 3_ Liquid&ate
1000
TR spectrum
Flaman
ape&rum
a00
600
400
of meso-3.4-dibromohexane
at ca
of meso-3.4dEbromohexme
80 K.
at morn
mperatule.
248 TABLE
1
R(liq.)
=oiq-)
1461m
1462s
IR(sol_)
RWq-)
Wliq-)
IR(M_II.)
953W 1465s
1422~1s
1288m
12019
1438ms 1383s 1356w 1344vw 132% 12936 1275m 1253~ 1205m 1191m 1153s
13ahs
903m
1342m 1315vw
P69m 807s
127Chs 12E5ms 12Olw
673m 648~s 625~s
1167ms
533s
lCY34m 105Oms
423m 388~
1139m 109ow 1056m
912rw 896mw
904w
884W
8848
866m ea805sh 793s 670w 617~ 5596 527m 48Om 420~
1033w 1001vw
1036ms
361m 3159 192vvs
550s 485m T
I 1036~ 1015w 997w
791s
JlO
n0
data !
has a center of symmetry. The very strong Reman band at 648 cm-’ must be the other C-Br sxetch band of this confo-rmer. It is absent in the IR spectrum, and the tw, C-Br stretches of the c1 conformer of 2,3dibromobukne were determined to be 547 (IR) and 642 cm-’ (El, calculated) [3] _ For XCHzCHBrCHBrCHIX (X = Cl, Br), the conformer analogous to conformer A (Fig- 4) is apparently the one present in the crystalline solid. Since the slxGghtchain hydrocarbons [4], n-all& chlorides 151, bromides [S], iodides [7], and other compounds also crystallize in the planar zigzag arrangement of carbon atoms, it is very likely that conformer A is the one present in the solid state of DBH. Coincidences of several Raman bands with liquid-state IR bands that disappear on solidification indicate either accidental coincidences for conformer B (Fig- 4) or the presen ce of a conformation that does not have a center of symmetry, such as conformer C, or both these possibilities Accidental coincidences will undoubtedly occur because of the large number of fundamental vibrations, but such coincidences are less likely in thf2 500-700 cm-' region. Observation of both IR and Raman bands at ca. 670, 650, aud 530 cm-’ indicates the presence of a conformer without a center of symmetry. Although the IR and Raman bands at ca. 620 and 530 cm-’ differ by 8 and 6 cm-l, respectively (617 and 625; 527 and 533 cm-’ ), it is assumed that, these are coincidences and that the differences are due to the uncertainty in the Raman values because of large slit width_
C Fig. 4. Most
probable
conformations
of mw-3,4-dl%romohexane.
Of the ten liquid&ate IX bauds that are absent in the solid-state spectrum, eight have Raman counterparts. This confirms the presence of at least one conformer that does not have a center of symmetzy. Th&e is insuf%zient evidence to conclude that the other centrosymmetric conforn~er is present. The IR. and Raman frequencies of DBH and the othertwo cer&osymmetric dihromo compounds (1,3) are all quite close (Raman = 635,642,647 cm-’ ; IR = 562, 547, 559 cm-’ )_ Examination of the normal vi.bratiDnsS~PWSthe frequency of the Raman-active C-Br stretching vibration should be higher than that of the m-active C-Br stretch because of the interaction of the Raman-active stretch with the middle C-C sWztch_ This i&era&ion is forllidden in the W. nzso-2.3.4,5-Tetmbromohexane (TBH) can titin two centrosymmetiical conformations analogous to those of tetrabromobutane (2). In one conformer, the six carbons are coplanar, and in the other conformer, four carbons and two bromines are coplanar. Jmed and Raman sp2ctra of the solid at room t&perature are shown in Figs_ 5 and 6, and the observed wavenumbers are listed in Table 2. Although there are a few coincidences of IX and Raman frequencies, the lack of coincidence of most bands shows the molecule ti have a center of symmetry. There are two exba bwds in the C-Br stretching region of the spectra. The weak Raman band at 696 cm-’ can be explained as the (Raman active only) combinrltion mode (191 + 504), and the m doublet at 670, 657 (1111-lis assurmedto be due to crystal field splitting. In order to check to see if the doublet at 670,657 cm-l is indeed due ti only one C-Br stretch, =d to check for the presence of otitir &_?formers in solution, IR spectra were obtained for a saturated solution of TBH in carbon dude. Although satumted, the solutio:~ was mute (ca l-2%),
250
1400
1600
1200
1000
BOO
600
400
CM-’
Fig_ 5. Partial solidstate IFt spectrum of meso-2-3,4,5_tetra!xomohsane tire
-
1600
1400
1200
1000
am
GO0
400
at room tempera-
I
200
0
CM-’
Fig. 6. Partial solid&ate temperature.
Raman speclnun
of meso-2.3,4.5-tetrabromohexzne
at room
251 TABLE
2
lnErar&andRaman
qQl-1 1447w
wavenumbersfor
-~ W-=L)
nt(6ol’n)
N-l-1
1380
922vw 88Qmw 706s
14516 144oms
1396vw 1384s
meso-2,3.4.5-tetrab~~~h~e .WSlLPl.)
IFt(&iol’n.)
98%
966
881s
875
696W
1349vw 133OwL.
670s 669
1206~ 1198m
1046mw 1026mw 1012w
1323m 12608 1209m
1318 1253 1203
657s 647s 67%
575
504S
1148m 1112mw 1045m
1145 1102 1042
312s 191v6 151
473m 401s t UO
T cEl3
1
and most bands absorbed only 5-10% (ca 90% ‘I’ with the background at 100%). It is evident, however, that there is only one band at the position of the solid-state CkBr doublet. In addition, there are no bands present that are absent in the solid-state spectrum, which indicates the presence in solution of only the one conformer that is present in the solid. This behavior is a little surprisiig, and differs from that of 1,2,3,4_tekabromobute (2), for which quite a few bands appeared in the solution spectra that were absent in the solid-state spectrum, show&g the presence of one or more additional conformers in solution_ An attempt was made to dissolve some TRH in a polar solvent (acetonitrile), but it wae ins;oluble_ The solid was also placed between two salt plates in a heated cell m an attempt to obtain an IR spectrum of the liquid above 180°C. However, ‘he solid sublimed before melting. A melting point had easily been obt&ecil with the compound in a capillary tube. The C-Y& &retcb.ing frequencies in TBH are higher than expected and are, in fxt, higher than in 1,2,3,4-~tmbromobuiane, even though all four bromides in ‘I’RH are bonded to secondary carbons and two of the bromides in TBB are bonded to primary carbons. ACKNOWLEDGEMEKTS The
Texas, work.
author is grateful to The Robert A. Wekh Foundation, Ho-us&on, and to the Killgore Research Center for .Gnancial support of this
252 RFiFSRENC63 1 2 3
G. A Crowder, J. Ramam sp-_. El (1979) 206. G.ACrowder.J.Raman S~,ectro~., 8 (1979) 320. R. G. Snyder, J_ Mol. Spectrosc_, 26 (1966) 273.
4 J. H. Schachtwhneider and FL G. Snydc, 6 R. G. Snyder and J. H. Schachtschneider, 6 7
G. A G_ A
Crowder Crowder
Spectrochim. Acta, 19 (1963) 117.
J. MoL Spech-osc_, 30 (1969) and M:. Jalilian, Can. J_ Spectrosc., 22 (1977) 1. ard S_ Ali, J. MoL Sh-uct, 25 (1975) 377_
290.
of golecuZar Sfrrrcrurz, 131(198S) Sciace Publishers B-V_, Ams+dam
ViBRATIoNAL
L%k’JXA
OF CENTFkOSYYM&ETRIG MOLECEXZS
Part HI_ meso-3,4KGbromohexane
i-3. A
..245-262 - F’rinted in The Netherlands
and meso-2,3,4&tekahromohexane
CROWDER
Depmfment (l&&iv&d
of Chemisfry.
WestT&us State
University.
Canyon,
Texas
79016
(U-S_&)
24 May 19Fs)
Liquid and s&id-state infra& and liquid-state Raman spectra were obtained for meso3,4dibromohexane and meao-2.3.4.5-tetrahromohesane‘I%e spectra show tie dihromotieme to erist as-2wo or more ccnformatio~_ in the neat liquid, including one that is cenizosymmeiric and one. thet is not centrosynunetric. The solid erkts only as one of tie This confc0xnation probably has all six two posible centrosymmetric conformstions. ~arbonx coplanar. The fetrahromc;7exa.ue ia a solid at rc,om temperatare and there is c&y one conformer present. The hck of coincidence of F&man and infrared bands show that conformer tomhave a center of symmetryNo additional conformers were found in dilute carbon disumde solution_ INTRODUCTION
It has recently been shown that meso-2,3~ibro~:o-l,~chloIulbutane [1] and meso-1,2,3,4-tetmbromobuk~e [Z] exist in the crystalline state in the centrosymmelzkal conformation with all carbolls %nd primary halogen coplanar. It has also been shown that meso-2,3d&romobut’ane crystalhzes in the centro~~mmetrical conformation [3] _ Vibrational spectra have now been obtained for meso-3,kIibromohexane and meso-2,3,4,S&rabromohexzme in order to compare the coizformational behavior of these compounds with the skructurahy similar compounds already studied_ EXPERIMEN’I’AL
meso-3,4-Dibromohexae was prepared by the stereospecific bromination of tiuns-313exene with CC& as solvent. The product was distilled and then redistilled, both times at reduced pressure. A fi-action boiling at 83-84”C/15 Torr each time was collected and. used. The spectra before and after the second distillation showed no differences, and gas chromatqraphic ana@rsis indicated the presence of only one compound_ meso-2,3,4.5-Telxabromohexane was prepared,_:in the same way as the dibromohexane, by bromination of tians,trans2,!Chexadiene. The productwas a white solid, wrich. was r~rystalhzed from CRC13~(mp. 180” C). 0022-2~60/35/~03.30
Q 1985
Elsevier
Science
Publishers
B-V_
246 were obtained with a Reclunan R-12 s_pectkphotometer m-1 FTIR spectrometer and Reman spectra vrere obtained &h a Beckman Model 700 spectrometer equipped with a Coherent R-ad$ai tioa Labs CR-2 Arron ion laser. The 488.0 nm line Y&SE&_ hhred
spectra
or a Nicolet
RESULTS
AND
DISCUSSION
Infmredspectraofmeso -3&dibromohex& (DBH) zire shown in Figs-l -and 2, and the Raman spectrun of the liquid is shown in Fig.3. The observed bands are listed ic Table 1. The C-Br &ret&kg frequencies of alI possible conformers of DRX would lie in the 500-700 cm-’ region. Liquid-state lR and Raman spectra show bands in this region at 670, 617, 559, 527 (IR) and at 673, 648, 625, and 533 cm-’ (R). Observation of this many bands indicates the presence of more than one conformation. In an effort to isolate bands due to one conformation, tied spectra were obtained for the solid, which was formed by cooling a liquid Glm to ca 80 K. The solidstate TR spectrum (Fig. 2) shows only the.550 cm-’ band in the C-Br stretch region. The z&appearance of the o+her bands in this region verifies the presence of rotational isomers_ Although there are a few coincidences of solid-state IR and liquid-state Raman bands, most of the solid-state lR bends do not have Ramen counterparts, including nearly all the strong IR. bands. It can therefore be concluded that the conformer preseu tinthesolid
I 1600
1400
1200
loo0
J
800
000
400
m-1
Fig_ 1. Partial
liquid&ate IR spectium of me60-3.4-dilxomoherze
at r&m tempmature.
247
%T
l-
1600
1200 CM-’
1400
Fig. 2. Partial solid-state
Fig_ 3_ Liquid&ate
1000
TR spectrum
Flaman
ape&rum
a00
600
400
of meso-3.4-dibromohexane
at ca
of meso-3.4dEbromohexme
80 K.
at morn
mperatule.
248 TABLE
1
R(liq.)
=oiq-)
1461m
1462s
IR(sol_)
RWq-)
Wliq-)
IR(M_II.)
953W 1465s
1422~1s
1288m
12019
1438ms 1383s 1356w 1344vw 132% 12936 1275m 1253~ 1205m 1191m 1153s
13ahs
903m
1342m 1315vw
P69m 807s
127Chs 12E5ms 12Olw
673m 648~s 625~s
1167ms
533s
lCY34m 105Oms
423m 388~
1139m 109ow 1056m
912rw 896mw
904w
884W
8848
866m ea805sh 793s 670w 617~ 5596 527m 48Om 420~
1033w 1001vw
1036ms
361m 3159 192vvs
550s 485m T
I 1036~ 1015w 997w
791s
JlO
n0
data !
has a center of symmetry. The very strong Reman band at 648 cm-’ must be the other C-Br sxetch band of this confo-rmer. It is absent in the IR spectrum, and the tw, C-Br stretches of the c1 conformer of 2,3dibromobukne were determined to be 547 (IR) and 642 cm-’ (El, calculated) [3] _ For XCHzCHBrCHBrCHIX (X = Cl, Br), the conformer analogous to conformer A (Fig- 4) is apparently the one present in the crystalline solid. Since the slxGghtchain hydrocarbons [4], n-all& chlorides 151, bromides [S], iodides [7], and other compounds also crystallize in the planar zigzag arrangement of carbon atoms, it is very likely that conformer A is the one present in the solid state of DBH. Coincidences of several Raman bands with liquid-state IR bands that disappear on solidification indicate either accidental coincidences for conformer B (Fig- 4) or the presen ce of a conformation that does not have a center of symmetry, such as conformer C, or both these possibilities Accidental coincidences will undoubtedly occur because of the large number of fundamental vibrations, but such coincidences are less likely in thf2 500-700 cm-' region. Observation of both IR and Raman bands at ca. 670, 650, aud 530 cm-’ indicates the presence of a conformer without a center of symmetry. Although the IR and Raman bands at ca. 620 and 530 cm-’ differ by 8 and 6 cm-l, respectively (617 and 625; 527 and 533 cm-’ ), it is assumed that, these are coincidences and that the differences are due to the uncertainty in the Raman values because of large slit width_
C Fig. 4. Most
probable
conformations
of mw-3,4-dl%romohexane.
Of the ten liquid&ate IX bauds that are absent in the solid-state spectrum, eight have Raman counterparts. This confirms the presence of at least one conformer that does not have a center of symmetzy. Th&e is insuf%zient evidence to conclude that the other centrosymmetric conforn~er is present. The IR. and Raman frequencies of DBH and the othertwo cer&osymmetric dihromo compounds (1,3) are all quite close (Raman = 635,642,647 cm-’ ; IR = 562, 547, 559 cm-’ )_ Examination of the normal vi.bratiDnsS~PWSthe frequency of the Raman-active C-Br stretching vibration should be higher than that of the m-active C-Br stretch because of the interaction of the Raman-active stretch with the middle C-C sWztch_ This i&era&ion is forllidden in the W. nzso-2.3.4,5-Tetmbromohexane (TBH) can titin two centrosymmetiical conformations analogous to those of tetrabromobutane (2). In one conformer, the six carbons are coplanar, and in the other conformer, four carbons and two bromines are coplanar. Jmed and Raman sp2ctra of the solid at room t&perature are shown in Figs_ 5 and 6, and the observed wavenumbers are listed in Table 2. Although there are a few coincidences of IX and Raman frequencies, the lack of coincidence of most bands shows the molecule ti have a center of symmetry. There are two exba bwds in the C-Br stretching region of the spectra. The weak Raman band at 696 cm-’ can be explained as the (Raman active only) combinrltion mode (191 + 504), and the m doublet at 670, 657 (1111-lis assurmedto be due to crystal field splitting. In order to check to see if the doublet at 670,657 cm-l is indeed due ti only one C-Br stretch, =d to check for the presence of otitir &_?formers in solution, IR spectra were obtained for a saturated solution of TBH in carbon dude. Although satumted, the solutio:~ was mute (ca l-2%),
250
1400
1600
1200
1000
BOO
600
400
CM-’
Fig_ 5. Partial solidstate IFt spectrum of meso-2-3,4,5_tetra!xomohsane tire
-
1600
1400
1200
1000
am
GO0
400
at room tempera-
I
200
0
CM-’
Fig. 6. Partial solid&ate temperature.
Raman speclnun
of meso-2.3,4.5-tetrabromohexzne
at room
251 TABLE
2
lnErar&andRaman
qQl-1 1447w
wavenumbersfor
-~ W-=L)
nt(6ol’n)
N-l-1
1380
922vw 88Qmw 706s
14516 144oms
1396vw 1384s
meso-2,3.4.5-tetrab~~~h~e .WSlLPl.)
IFt(&iol’n.)
98%
966
881s
875
696W
1349vw 133OwL.
670s 669
1206~ 1198m
1046mw 1026mw 1012w
1323m 12608 1209m
1318 1253 1203
657s 647s 67%
575
504S
1148m 1112mw 1045m
1145 1102 1042
312s 191v6 151
473m 401s t UO
T cEl3
1
and most bands absorbed only 5-10% (ca 90% ‘I’ with the background at 100%). It is evident, however, that there is only one band at the position of the solid-state CkBr doublet. In addition, there are no bands present that are absent in the solid-state spectrum, which indicates the presence in solution of only the one conformer that is present in the solid. This behavior is a little surprisiig, and differs from that of 1,2,3,4_tekabromobute (2), for which quite a few bands appeared in the solution spectra that were absent in the solid-state spectrum, show&g the presence of one or more additional conformers in solution_ An attempt was made to dissolve some TRH in a polar solvent (acetonitrile), but it wae ins;oluble_ The solid was also placed between two salt plates in a heated cell m an attempt to obtain an IR spectrum of the liquid above 180°C. However, ‘he solid sublimed before melting. A melting point had easily been obt&ecil with the compound in a capillary tube. The C-Y& &retcb.ing frequencies in TBH are higher than expected and are, in fxt, higher than in 1,2,3,4-~tmbromobuiane, even though all four bromides in ‘I’RH are bonded to secondary carbons and two of the bromides in TBB are bonded to primary carbons. ACKNOWLEDGEMEKTS The
Texas, work.
author is grateful to The Robert A. Wekh Foundation, Ho-us&on, and to the Killgore Research Center for .Gnancial support of this
252 RFiFSRENC63 1 2 3
G. A Crowder, J. Ramam sp-_. El (1979) 206. G.ACrowder.J.Raman S~,ectro~., 8 (1979) 320. R. G. Snyder, J_ Mol. Spectrosc_, 26 (1966) 273.
4 J. H. Schachtwhneider and FL G. Snydc, 6 R. G. Snyder and J. H. Schachtschneider, 6 7
G. A G_ A
Crowder Crowder
Spectrochim. Acta, 19 (1963) 117.
J. MoL Spech-osc_, 30 (1969) and M:. Jalilian, Can. J_ Spectrosc., 22 (1977) 1. ard S_ Ali, J. MoL Sh-uct, 25 (1975) 377_
290.