Study of the E-Z stilbene isomerisation in perchlorotriphenyl-methane (PTM) derivatives

Article abstract of DOI:10.1039/c6ra28618f

The E-Z isomerisation of two perchlorotriphenylmethane derivatives containing stilbene units has been investigated, both thermally and photochemically. The irreversibility of the E → Z isomerisation in both compounds is experimentally demonstrated and sup

Full text of DOI:10.1039/c6ra28618f

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Study of the E–Z stilbene isomerisation in
perchlorotriphenyl-methane (PTM) derivatives†
Cite this: RSC Adv., 2017, 7, 15278
a
b
a
F. Bejarano,‡ I. Alcon,‡ N. Crivillers, M. Mas-Torrent, ^a S. T. Bromley,^bc J. Veciana^a
*
a
*
and C. Rovira
Received 23rd December 2016
Accepted 24th February 2017
The E–Z isomerisation of two perchlorotriphenylmethane derivatives containing stilbene units has been
investigated, both thermally and photochemically. The irreversibility of the E / Z isomerisation in both
compounds is experimentally demonstrated and supported by density functional calculations.
DOI: 10.1039/c6ra28618f
rsc.li/rsc-advances
The photoinduced E–Z isomerization phenomenon has been objects with unprecedented shapes (i.e., owers, cones, bres,
a longstanding interesting topic in organic and inorganic etc.) following the so-called “hydrophobic–amphiphilic”
chemistry as well as in biology. The change in the functional approach.⁷ Moreover, by chemical modication of the phenyl
properties depending on the molecular structure of the substitution pattern, robust micro-capsules that could encap-
different meta-stable isomers has been exploited for many sulate hydrophilic contents were prepared. Interestingly, such
applications in biochemistry, pharmacology and supramolec- hydrophilic contents were neatly released upon UV irradiation
ular chemistry.¹ The most representative isomeric switchable due to photochemical decomposition leading to a phenan-
systems are azobenzenes² and stilbenes.³ Both, upon illumina- threne derivative.⁸ Further, chemically bonded self-assembled
tion with a specic wavelength, can undergo a reversible photo- monolayers (SAMs) on gold were previously prepared using
isomerisation between the trans and cis conformation. They the E isomer of compound 1 (Scheme 1).⁹ In this case, the SAMs
have been extensively investigated as molecular switches⁴ and were employed as precursors to form the organic free radical
also have led to many different applications such as molecular derivative which has been shown to constitute an excellent
motors⁵ or solar-thermal fuels.⁶ In the latter, solar energy is platform for the fabrication of robust molecular memories due
stored in the chemical bonds by photoconversion and, upon to its electroactive character.¹⁰ In view of the interesting prop-
activation, the stored energy is released in the form of heat. erties of the functional materials prepared employing the PTM
Here we study, both photochemically and thermally, the E–Z derivatives as building blocks, we were interested in studying
isomerisation of perchlorotriphenylmethane (PTM) derivatives the isomerisation processes that these systems can undergo
containing a stilbene unit with one of their phenylene rings when they are irradiated or heated.
substituted with four chlorine atoms and
a
per-
Compounds 1 and 2 were obtained through a Wittig and
chlorodiphenylmethyl group at the para position. This a Horner–Wadsworth–Emmons reaction, respectively. In the
phenomenon is presented herein with the study of two differ- case of 1, the reaction was carried out between the PTM phos-
ently substituted stilbene derivatives (Scheme 1). This family of phonium bromide salt and the 4-(acetylthio)benzaldehyde
molecules is very appealing since it has been demonstrated (see details on the synthesis in ref. 11). Molecule 2 was
that, with a proper design, they can be excellent building blocks prepared through the coupling of PTM phosphonate and
to form functional supramolecular nano- and micro-structures
driven by Cl/Cl and Cl/phenyl interactions. Indeed, very
recently, it was demonstrated that PTM moieties substituted
with p-vinylphenylene groups functionalised with long alkyl
chains can be employed to prepare molecular micro-scale
a
`
Institut de Ciencia de Materials de Barcelona (ICMAB-CSIC), Networking Research
Center on Bioengineering, Biomaterials and Nanomedicine (CIBER-BBN), Campus de
la UAB, 08193 Bellaterra, Spain. E-mail: cun@icmab.es; mmas@icmab.es
b
`
´
´
´
´
Departament de Ciencia de Materials I Quımica Fısica, Institut de Quımica Teorica i
Computacional, Universitat de Barcelona (IQTCUB), E-08028 Barcelona, Spain
c
´
Instiuicio Catalana de Recerca i Estudis Avançats (ICREA), 08010 Barcelona, Spain
† Electronic supplementary information (ESI) available. See DOI:
10.1039/c6ra28618f
Scheme 1 Isomerisation of PTM–SAc (1) and PTM–Br (2); E-1/2 to Z-1/2.
‡ Equally contributed.
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Table 1 Time evolution of the relative area of the HPLC chromato-
gram peaks at retention times of ca. 12 and 15 min for compound 1
during sample irradiation
4-bromobenzaldehyde (synthesis adapted from ref. 12). It is
known that the H-NMR chemical shi of the hydrogen atoms
1
of C]C groups, as well as their coupling constant J, allows for
the identication of the two possible isomers that can be ob-
tained from these synthetic routes. For the compounds pre-
sented here, the J value of the E isomers is around 17 Hz, while
for the Z isomers it is around 12 Hz. It was determined that the E
isomer was the major component of the reaction mixtures, with
a ratio of ca. 92% and 99% for E-1 and E-2, respectively (deter-
%
%
(Z/E)
Time (min)
Area (Z-1)
Area (E-1)
Peak areas ratio
0
10
46
102
115
145
7.5
23.0
67.7
75.5
87.9
88.8
92.5
77.0
31.3
24.5
12.1
11.2
0.08
0.30
2.16
3.08
7.26
7.93
1
mined by H-NMR signal integration).
In order to follow and quantify the E/Z isomerisation
processes for compounds 1 and 2, High Performance Liquid
Chromatography (HPLC) was employed using reversed-phase
conditions, at room temperature and under an isocratic the expected Z-1 compound. The same analysis was performed
regime. Mixtures of acetonitrile/tetrahydrofuran (9 : 1) and for compound 2.
acetonitrile/chloroform (8 : 2) were found as optimal conditions
for an adequate separation of the corresponding isomers for 1 copy shows that there is an overlap of the absorption spectra of
and 2, respectively.
both isomers (see ESI†). In addition, the Z isomer absorbs white
The characterization by ultraviolet-visible (UV-vis) spectros-
Aer reaching a good separation of the two isomers, we light more poorly than the E isomer. For these two reasons the
proceeded to study the photo-isomerisation conversion from back Z / E phoisomerization could not be carried out.
the E to the Z form of 1 and 2. The samples were irradiated with
Since the most thermodynamically favoured isomer for stil-
a Hg(Xe) lamp 300 W placed at around 30 cm from the sample. benoid compounds is usually the E isomer, we proceeded with
In the case of 1, a 0.07 mM solution in a THF/ACN (1 : 1) mixture the study of the thermally induced conversion of the Z form
was used for this experiment. To follow the evolution of the back to the E. To do that, the photostationary state mixture
isomerisation process, several aliquots were taken during the obtained by irradiation was reuxed in different solvents:
irradiation time and analysed by HPLC. Fig. 1 shows the cor- chloroform, tetrahydrofuran, cyclohexane, toluene and
responding chromatograms and the retention times. The rela- o-dichlorobenzene for, at least 3 hours. These solvents do not
tive peak areas (in %) are depicted for each analysed aliquot in only allow access to different heating temperatures, but also
Table 1. See ESI† for the monitoring performed for 2.
they provide different polarities of the media, as well as inter-
As expected, the Z/E ratio increases in both cases during the actions between the solvent and the PTM derivatives through
irradiation time until the photostationary state is reached. The their ability to form p–p and Cl–Cl interactions. Again, the
¹H-NMR (see ESI†) of the sample aer irradiation conrmed solution evolution was followed by HPLC. In this case, the
that the peak at a retention time of 12 minutes corresponds to thermal back conversion was not observed for either compound
1 or 2. This result is in agreement with previous studies which
determined an activation barrier for the Z / E isomerisation
for stilbenoid compounds of the order of 1.9 eV (43.8 kcal
mol^ꢀ1), which makes the thermal back reaction unlikely.¹³
We attempted to carry out the PTM Z / E isomerisation
process using catalytic amounts of iodine. This is an established
methodology to convert isomeric mixtures to the E derivative.¹⁴
The obtained photostationary state mixture of 2 was dissolved
in toluene (0.022 M) with iodine (0.03 eq.) and the solution was
reuxed for 5 hours. The evolution of the mixture was followed
by HPLC and no back isomerisation was observed by HPLC
monitoring. Then, 0.03 more equivalents of I₂ were added and
the solution was reuxed 19 additional hours. Aer such a long
period of time at high temperature many products of decom-
position appeared (see Fig. S5 in ESI†) but no isomer E forma-
tion was observed. Therefore, this suggests that back
isomerisation, in the best case, is less favoured than several
decomposition pathways.
Density functional theory (DFT) calculations were carried out
to better understand the irreversible isomerisation process
Fig. 1 Evolution of the HPLC chromatograms obtained upon irradia-
Z / E observed for both PTM derivatives 1 and 2. It is known
tion of E-1 in a solvent mixture of THF/ACN (1 : 1). Experimental
that, unlike azobenzene derivatives, in ethylene derivatives
photo-activated twisting of the C]C bond is the main mecha-
nism for E–Z isomerisation¹⁵ as represented with the red arrow
conditions: 25 ^ꢁC, mobile phase THF/ACN (10/90), stationary phase
ODS, UV detector with a fixed wavelength of 230 nm and a flow of
1 mL min^ꢀ1
.
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on the stilbene structure in Fig. 2a. To obtain the ground state conformer (4 ¼ 180^ꢁ), with the perpendicular conformation (i.e.
energy prole associated with such a twisting process in 4 ¼ 90^ꢁ, 270^ꢁ) being the most energetically unstable by 1.9 eV
compounds 1 and 2, we systematically varied the corresponding (i.e. the E 4 Z energetic barrier height, see ESI†). These results
C]C dihedral angle and performed constrained optimisations are fully in accordance with previous studies.^13,14 Time depen-
of the molecular structure for each conformation. In all cases, dent DFT (TD-DFT) calculations were then used to obtain
the E conformer (4 ¼ 0^ꢁ, 360^ꢁ) is slightly more stable than the Z approximate absorption spectra for E and Z conformers for both
derivatives 1 and 2. For the E conformers we found the most
intense peak at 340 and 345 nm (for 1 and 2, respectively). In the
corresponding Z conformers, these peaks slightly shi towards
higher energies (315 and 317 nm for 1 and 2, respectively) and
decreases in intensity by ꢂ60%. These calculations coincide
with our experimental UV-vis spectroscopy measurements (see
ESI Fig. S1†), where the peak at ꢂ310 nm for the E conformer
decreases in intensity upon photo-generating the Z conformer
and shis towards higher energy wavelengths. This UV-vis band
variation has been observed for other stilbene derivatives,
where such optical absorptions were associated with the photo-
activation of the C]C moiety.¹⁶
The higher absorbance of the E conformer might explain the
high production of the Z conformer upon light absorption.
However, the thermal irreversibility of the photo-isomerisation
of Z towards the E isomer (even under I₂ catalyzed conditions)
suggests that the different UV-vis absorption characteristics of
the two conformers may not fully explain the experimental
ndings.¹⁶ In the C]C twisting process assessed by constrained
DFT optimizations (see ESI†) we found that, for both 1 and 2,
the aryl ring groups bonded to the ethylene unit had to be
twisted to specically chosen angles (black arrows on stilbene
structure in Fig. 2a) in order to prevent steric interactions and
hence allow the rotation around the C]C bond axis (red arrow
on stilbene structure in Fig. 2a). The key role of such aryl ring
twist angles for the E 4 Z photo-isomerisation has been
demonstrated both theoretically¹⁷ and experimentally,¹⁸ and
proven to be more relevant for the Z / E process¹⁹ than for the E
/ Z one.²⁰ Based on this, we performed ab initio molecular
dynamics (AIMD) simulations at 450 K (see computational
details below) to compare the thermal uctuations of such aryl
ring twist angles in compounds 1 and 2 and stilbene (where the
E
4 Z isomerisation is completely reversible) in each
conformation.
Extracting the twist angle of the central ethylene unit (red
arrow in Fig. 2a) we could nd that, for all cases, the C]C bond
hardly rotates (see ESI†). This is in full accordance with its
associated high twisting energy and corroborates the need for
light irradiation to induce the E 4 Z transition, even at high
temperatures (see ESI†). In contrast, by following the variation
in the twist angles of the aryl rings with respect to the ethylene
unit (black arrows in Fig. 2a), it is possible to observe
signicant differences between the E and Z conformer proles
(Fig. 2b and c).
For both PTM derivatives and stilbene in the E conformation
Fig. 2 (a) Fully optimized structures of the E-isomers of PTM deriva- such aryl ring twist angles uctuate signicantly over time
tives 1 and 2, and stilbene. The coloured arrows on the structure of
stilbene highlight the important twist angles (red: main C]C axis,
black: twist angles of the aryl groups bonded to the ethylene unit). (b)
and (c) Evolution of the twist angles of the aryl groups bonded to the
(Fig. 2b) which is consistent with the little steric interaction
between the two aryl ring groups bonded to the C]C unit. For
stilbene in the Z conformation the two aryl rings tend to keep
rotating in opposite directions leading to a gradual increase in
the magnitude of the associated twist angle (see blue lines in
ethylene unit for each molecule (see legends) during 4 ps of an AIMD
run at 450 K for the E and Z conformers respectively.
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Fig. 2c). Although in this case the two rings are close to each
other, by counter rotating in this manner they are able to avoid
signicant steric hindrance. In the Z conformers of derivatives 1
and 2, however, the aryl ring twist angles quickly converge to
xed values of about 60^ꢁ. The lack of rotation in these cases
comes from two different factors. From one side, the bulky PTM
group possesses relatively high inertia to move which impedes
the rotation of that bulky group attached to the ethylene unit.
Also, the close proximity of the ortho-chlorine atoms within the
PTM unit with the opposite aryl ring (see the Z-1 structure in
Fig. 2c) gives rise to large steric constraints which prevent the
free rotation of the brominated aryl ring. Hence, overall, the
rotational freedom of both groups bonded to the ethylene unit
in the Z conformation of 1 and 2 is signicantly suppressed.
As noted above, when calculating the twisting of derivatives 1
and 2 about the C]C bond specic twist angles of the aryl ring
groups are needed to avoid signicant steric interactions and
allow the isomerisation to occur. In the E conformer such
specic aryl ring twist angles should be easily accessible due to
the freely rotating behaviour in such conformation for 1, 2 and
stilbene (see Fig. 2b). However, in the Z conformation, aryl rings
in compounds 1 and 2 do not rotate due to steric interactions
between the two aryl ring groups and the larger inertia of the
PTM unit. Such an effect does not occur for stilbene (blue curve
in Fig. 2c), where the E 4 Z isomerisation is completely
reversible.¹⁶ These results suggest that the complete and irre-
versible formation of Z isomers under light irradiation (Fig. 1)
for PTM derivatives 1 and 2 could be at least partially explained
by the lack of free rotation of their aryl rings in the Z confor-
mation, causing a kinetic blockage. This suggestion may also
help explain why even when using a chemical catalyst (I₂) the Z
Fig. 3 (a) Mechanistic scheme of the isomerisation process taking
place in stilbene (a) and the PTM derivative 1 (b), under the effect of
light irradiation and temperature. In both cases light opens the central
double-bond, which allows the free rotation of the ethylene unit due
to thermal fluctuations (RT). Contrary to stilbene, PTM derivatives 1 and
2 get kinetically blocked in the Z conformation, shifting the equilibrium
towards such conformation.
Experimental details
/ E process does not seem to occur and also the uniqueness of Synthesis of 1 was carried out as previously reported.¹¹
these observations as compared to less hindered stilbene
derivatives reported in previous studies.¹⁶ Therefore, as repre-
Characterization of E-1
sented schematically in Fig. 3a, in stilbene the E and Z confor-
UV-vis: l_max (THF)/nm 222 (3/dm³ mol^ꢀ1 cm^ꢀ1 168 894), 297
mations stay in an equilibrium under conditions of light
(15 709). FT-IR (KBr): n_max./cm^ꢀ1 3032, 1712 (CO), 1636, 1532,
irradiation and high temperature, due to the high conforma-
1493, 1406, 1368, 1351, 1338, 1297, 1240, 1139, 1118, 1115,
tional exibility of the molecule. Contrary, as sketched in
1088, 969, 943, 871, 718, 688, 668, 648, 613, 536, 528, 507, 484.
Fig. 3b, in PTM derivatives 1 and 2 the E conformation is
¹H-NMR: d_H(500 MHz; CDCl₃; Me₄Si) 7.60 (2H, d, J ¼ 8.5 Hz,
kinetically blocked, even when the ethylene unit is electronically
ArH), 7.48 (2H, d, J ¼ 8.5 Hz, ArH), 7.13 (1H, d, J ¼ 17 Hz), 7.09
excited with light, which impedes the Z / E process and,
(1H, d, J ¼ 17 Hz, –(C₆Cl₄)–CH]CH–), 7.06 (1H, s, –(C₆Cl₄)–
consequently, shis the isomerisation equilibrium towards the
CH]CH–), 2.48 ppm (3H, s, –CH₃). ¹³C-NMR: d_C(101 MHz;
less stable Z isomer.
CDCl₃; Me₄Si) 137.22, 136.88, 136.82, 136.24, 135.97, 134.82,
In summary, we have studied the photo-induced isomer-
134.75, 134.58, 134.53, 133.68, 133.65, 133.37, 133.2, 133.14,
isation of E-p-vinylphenylene functionalised perchloro-
132.21, 132.18, 132.03, 128.19, 127.28, 124.11, 56.34 (a), 30.00
triphenylmethane derivatives to the
Z
isomer. The
(–CH₃). MALDI-ToF (negative mode) (C₂₉Cl₁₄H₁₀SO, M ¼ 902.8)
isomerisation process has been monitored by HPLC which
reveal an almost complete isomerisation. The higher
absorption ability of the E isomer as compared to the Z
isomer at the same wavelengths prevents the back Z / E
m/z (M ꢀ 902.08); (M ꢀ 43 859.08), (M ꢀ 70 832.08).
Characterization of Z-1
isomerisation. No thermal back isomerisation takes place UV-vis: l_max (THF)/nm 222 (3/dm³ mol^ꢀ1 cm^ꢀ1 104 222), 254
although the E isomer is the most thermodynamically fav- (35 917), 285 (14 087). ATR-IR n_max./cm^ꢀ1 3125, 1711 (CO), 1534,
oured. Theoretical calculations point to the steric hindrance 1493, 1462, 1358, 1338, 1296, 1262, 1239, 1207, 1188, 1133,
within the Z conformers leading to a possible kinetic block- 1115, 1090, 1015, 946, 871, 835, 808, 764, 719, 709, 687, 678, 661,
ing of the Z / E transition as the effect contributing to the 646, 630, 611, 573, 550, 541. ¹H-NMR: d_H(600 MHz; CD₂Cl₂;
thermal irreversibility of the E / Z process.
Me₄Si) 7.30 (2H, d, J ¼ 8.5 Hz, ArH), 7.02 (2H, m, ArH and 1H
aH-PTM), 6.9 (1H, d, J ¼ 12 Hz, –(C₆Cl₄)–CH]CH–), 6.6 (1H, d, J
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¼ 12 Hz, –(C₆Cl₄)–CH]CH–), 2.38 (3H, s, CH₃) ppm. ¹³C-NMR: 132.94, 132.65, 132.02, 130.04, 125.48, 122.58, 108.39, 57.01 (a).
d_H(101 MHz; CD₂Cl₂; Me₄Si): d ¼ 193.87 (CO), 138.32, 137.52, MS (negative mode) (C₂₇Cl₁₄H₇Br, M ¼ 907.6) (m/z) (M ꢀ 1906.4).
136.98, 136.96, 135.43, 135.31, 134.84, 134.52, 134.37, 134.30,
134.05, 134.01, 133.93, 133.73, 132.92, 132.68, 129.08, 128.66,
127.88, 125.95, 57.01 (a), 30.48 (–CH₃). MS (negative mode)
DFT calculations
For assessing the isomerisation energy prole we twisted the
(C₂₉Cl₁₄H₁₀SO, M ¼ 902.8) m/z (M + 4906.4).
molecular skeleton about the ethylene double-bond axis from
0 to 360 degrees. At each point the molecular structure was
optimized while freezing the twist angle of the C]C bond.
These constrained optimizations were done using the hybrid
PBE0 functional^21,22 and a 6-311-G++ basis set as implemented
in the Gaussian09 code [Gaussian 09, Revision E.01, D. J. Fox,
Gaussian, Inc., Wallingford CT, 2009]. Within the same code,
the time-dependent DFT method^23–29 was used to calculate
absorption spectra. Ab initio molecular dynamics (AIMD)
simulations at 450 K were run for 5 ps (1 ps of equilibrations
plus 4 ps of production) using the Bussi–Donadio–Parrinello
thermostat.³⁰ For these calculations the PBE0 functional and
a “light” numerical basis set was used as implemented in the
FHI-AIMS code.^31,32
Synthesis of 2 (adapted from ref. 12): potassium tert-butoxide
(95 mg, 0.87 mmol) was added to a solution of diethyl
4-[bis(2,3,4,5,6-pentachlorophenyl)methyl]-2,3,5,6-tetrachloro-
benzyl phosphonate (500 mg, 0.57 mmol) in dry tetrahydro-
ꢁ
furan (10 mL) at ꢀ90 C, in a N₂/acetone bath. The resulting
yellow-orange ylide solution was stirred for 30 minutes. Then,
p-bromobenzaldehyde (188 mg, 1.04 mmol) dissolved in 4 mL of
dry THF was added drop-wise. The solution was allowed to stir
for 24 hours without changing the N₂/acetone bath, which
reached room temperature along the reaction. The reaction was
monitored by thin-layer chromatography (silica-gel). Once the
reaction nished, one drop of concentrated HCl was added to
the resulting dark purple solution, which turned on a yellow
suspension. The reaction mixture was extracted with water
(10 mL) and dichloromethane (10 mL). The phases were sepa-
rated and the aqueous phase was washed with further
dichloromethane (2 ꢃ 10 mL). The combined organic layers
were dried over anhydrous sodium sulfate, ltered and
concentrated under vacuum. Almost pure E-2 isomer (97%)
(473 mg, 92%) was obtained through purication by chroma-
tography (silica gel with hexane as eluent).
Acknowledgements
We thank Carlos Franco for his help with the HPLC analysis and
´
Amable Bernabe CTQ2016-80030-R for the MALDI-ToF charac-
terizations. We thank the Networking Research Center on
Bioengineering, Biomaterials and Nanomedicine (CIBER-BBN);
DGI (Spain) with projects BE-WELL CTQ2013-40480-R and
MAT2012-30924, and Generalitat de Catalunya (grant
2009SGR00516, 2014SGR97 and XRQTC). We also thank the EU
projects ERC StG 2012-306826 e-GAMES, ITN iSwitch (GA no.
642196), ACMOL (GA no. 618082) and CIG-ELECTROMAGIC
(PCIG10-GA-2011-303989). Spanish Ministry of Economy and
Competitiveness, through the ‘Severo Ochoa’ Programme for
Centres of Excellence in R&D (SEV-2015-0496). N. C. thanks the
RyC contract. F. B. acknowledges the FPU fellowship. F. B. is
enrolled in the Materials Science PhD program of UAB.
Characterization of E-2
UV-vis: l_max (C₆H₁₂)/nm 222 (3/dm³ mol^ꢀ1 cm^ꢀ1 107 000), 304
(29 000). FT-IR (KBr): n_max./cm^ꢀ1 3015, 1635, 1590, 1535, 1490,
1405, 1365, 1340, 1295, 1240, 1140, 1075, 1010, 965, 940, 870,
805, 790, 715, 645, 532, 495. ¹H-NMR: d_H(400 MHz; CD₂Cl₂;
Me4Si) 7.59 (2H, m, ArH), 7.48 (2H, m, ArH), 7.12 (1H, d, J ¼
16.6 Hz, –(C₆Cl₄)–CH]CH–), 7.07 (1H, s, aH-PTM) 7.06 ppm
(1H, d, J ¼ 16.6 Hz, –(C₆Cl₄)–CH]CH–). ¹³C-NMR: d_C(101 MHz,
CD₂Cl₂) d ¼ 137.70, 137.58, 137.05, 137.04, 136.63, 135.55,
135.48, 135.46, 135.26, 134.47, 134.37, 134.00, 133.98, 133.94,
133.91, 133.84, 132.89, 132.72, 132.37, 128.85, 124.22, 123.17,
57.09 (a). MS (C₂₇Cl₁₄H₇Br, M ¼ 907.6) (negative mode) (m/z) (M
ꢀ 1906.4). UV-Vis (C₆H₁₂) l(3) [nm (M^ꢀ1 cm^ꢀ1)] 304 (29 000); 222
(107 000).
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Characterization of Z-2
UV-vis: l_max(THF)/nm 221 (3/dm³ mol^ꢀ1 cm^ꢀ1 116 098), 284
(12 337). FT-IR n_max./cm^ꢀ1 3015, 1725, 1585, 1485, 1370, 1335,
1295, 1240, 1130, 1070, 1010, 830, 805, 760, 710, 680, 655, 640,
1
550, 530, 460, 425. H-RMN: d_H(400 MHz; CD₂Cl₂; Me₄Si) 7.39
(2H, m, ArH), 7.00 (1H, s, aH-PTM), 6.91 (2H, d, J ¼ 7.52 Hz,
ArH), 6.83 (1H, d, J ¼ 12.01 Hz, –(C₆Cl₄)–CH]CH–), 6.57 ppm
(1H, d, J ¼ 12.01 Hz, –(C₆Cl₄)–CH]CH–).¹³C-RMN: d_H(101 MHz;
CD₂Cl₂; Me₄Si) 138.25, 136.97, 136.95, 135.56, 135.39, 135.29,
134.52, 134.34, 134.30, 134.07, 134.03, 133.95, 133.71, 133.57,
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