Thienyl directed polyaromatic C-C bond fusions: S-doped hexabenzocoronenes

Article abstract of DOI:10.1039/c0cc05231k

With a view to combining the desirable electronic and photochemical properties of hexabenzocoronene (HBC) and the C-C bond forming capabilities of thiophenes, 1-(3-thienyl)-2,3,4,5,6-penta(4-tert-butyl-phenyl)benzene (1) was oxidised using FeCl₃

Full text of DOI:10.1039/c0cc05231k

View Article Online / Journal Homepage / Table of Contents for this issue
Dynamic Article Links
ChemComm
Cite this: Chem. Commun., 2011, 47, 3616–3618
www.rsc.org/chemcomm
COMMUNICATION
Thienyl directed polyaromatic C–C bond fusions: S-doped
hexabenzocoronenesw
a
a
ab
Colin J. Martin, Belen Gil, Sarath D. Perera and Sylvia M. Draper*^a
´
Received 28th November 2010, Accepted 20th January 2011
DOI: 10.1039/c0cc05231k
With
a view to combining the desirable electronic and
photochemical properties of hexabenzocoronene (HBC) and
the C–C bond forming capabilities of thiophenes, 1-(3-thienyl)-
2,3,4,5,6-penta(4-tert-butyl-phenyl)benzene (1) was oxidised
using FeCl₃. The resulting products, superaromatic thiophene
(2) and its 5,5⁰-dimer (3), are S-HBC systems and provide a new
pair of spectral comparators.
The enhanced reactivity of thiophenes and their polymer
forming capabilities mean that there are distinct and expanded
potential applications that arise upon the incorporation of
thiophene subunits into carbon frameworks.¹ Herein is
described the careful design of a polyphenylene precursor with
a strategically positioned 3-thienyl moiety and the formation
of a fully cyclised thienyl-hexabenzocoronene along with
its 5,5⁰ dimer. Although some sulfur containing polycyclic
aromatic hydrocarbons have been previously reported,² these
systems are the first sulfur containing hexabenzocoronenes.
The full photochemical and electrochemical characterisation
of these new molecules is discussed.
Scheme 1 The synthetic route via 1 of fully cyclised S-HBCs 2 and 3.
Polyphenylenes are readily formed from the [2 + 4] Diels–
Alder reactions of appropriately substituted alkynes and
cyclopentadienones.³ Monosubstitution on the polyphenylene
requires the use of an asymmetric alkyne such as (4-tert-butyl-
phenyl)(3-thienyl)acetylene (PhCCS).⁴ The reaction of this with
tert-butyl substituted tetraphenyl cyclopentadienone results in
the formation of monothiophene 1 which undergoes oxidative
cyclodehydrogenation in the presence of FeCl₃ (Scheme 1).
Looking at the products formed, the rationale behind the
choice of a 3-thiophene becomes self-evident; 1 provides two
carbon sites (2- and 4-) for subsequent C–C bond formation. On
complete cyclisation only one isomer of the product can be
formed, irrespective of the twist of the thiophene about its point
of attachment to the polyphenylene fragment (Scheme 2A).
Cyclodehydrogenation produces both thienyl-hexabenzo-
coronene 2 and its dimer 3 (each in 28% yield). The reactivity
of the 2-position in thiophenes is well-established, however the
Scheme 2 Twisted (A) and coplanar (B) conformations proposed for
the dimeric system 3.
formation of the 5,5⁰ dimer 3 appears to be possible only after
the precursor polyphenylene has been oxidised and aromatised.
This implies that in 1 the intramolecular cyclodehydrogenations
between both the 2- and 4-positions of the thiophene and the
polyphenylene core are more facile than the intermolecular
dimerisation at the 5-position.
The ¹H NMR spectrum of 2 shows five aliphatic signals for
the five sets of tert-butyl groups between d 1.89 and 1.72 ppm.
These integrate for nine protons each leaving eleven aromatic
methine signals for the hydrogens on the periphery of the
compound (Fig. 1). Ten of these (2–11, Fig. 1) resonate
between d 9.31 and 8.94 ppm but one appears more upfield
at d 8.22 ppm (1, Fig. 1). Through correlation spectroscopy
this has been assigned as the phenyl proton closest to the
sulfur atom. The rest were fully assigned using 2D correlation
and nOe experiments.
^a School of Chemistry, University of Dublin, Trinity College, Dublin 2,
Ireland. E-mail: smdraper@tcd.ie; Fax: +353 1-671-2826
^b The Chemistry Department, Open University of Sri Lanka,
Nugegoda, Sri Lanka
w Electronic supplementary information (ESI) available: Experimental
data along with tables of photochemical data are available. See DOI:
10.1039/c0cc05231k
For 3, aliphatic singlets for the tert-butyl groups are
observed between d 1.90 and 1.79 ppm, each integrating for
c
3616 Chem. Commun., 2011, 47, 3616–3618
This journal is The Royal Society of Chemistry 2011

View Article Online
1
Fig. 1 The H NMR spectrum of 2 (CDCl₃, 400 MHz, 25 1C).
Fig. 4 UV/Vis absorption spectra (chloroform, 10^ꢀ5 M) of 2 (dotted
line) and 3 (solid line).
fused thiophene unit. These peaks are affected upon
dimerisation—indicative of the additional intermolecular 5,5⁰
C–C bond fusion between the two thiophene units in 3, shifting
the oxidation peaks to higher potential in comparison with 2.
To further elucidate the electronic character of the
compounds photophysical investigations were carried out
(Tables S1–S3, ESIw). S-containing graphene monomer 2 exhibits
two intense structured absorptions (l_max 358 and 369 nm) (Fig. 4,
dotted line) similar to those of symmetric, alkyl substituted
hexabenzocoronene (HBC).⁵ These correspond to the b and p
absorption bands generally observed for HBCs.⁶ In addition
longer wavelength absorptions with l_max 408 and 432 nm are
seen; these p - p* transitions are usually symmetry forbidden in
all carbon HBC but appear in 2 due to its lower symmetry.
For the dimeric compound 3, the absorption (Fig. 4, solid
line) is slightly more intense than 2 but the spectrum exhibits a
similar profile, with the addition of a new absorption shoulder
that tails out to 550 nm. The appearance of this tail is
independent of concentration, precluding the formation of
any aggregated ground state species (concentration range
10^ꢀ3–10^ꢀ5 M). The new low-energy absorption could be due
to the increased conjugation that would arise if the two
graphene subunits in 3 become coplanar. If this is the case,
then it would reflect the proportion of coplanar molecules in
solution (Scheme 2B).⁷
1
Fig. 2 The H NMR spectrum of 3 (CDCl₃, 600 MHz, 25 1C).
eighteen protons. A total of ten aromatic signals, each
integrating for two protons, are observed between d 9.46 and
8.70 ppm (Fig. 2). These signals appear broader than those of
2, due to increased aggregation effects in this larger graphene.
1
Although the H NMR spectrum of 3 could not be assigned
fully, five pairs of aromatic signals (a–e) for the two protons
on each aromatic ring have been identified using TOCSY
spectroscopy. The signal at d 8.75 ppm has been assigned to
position c due to its proximity to the sulfur (Fig. 2).
In solution cyclic voltammetry experiments monothiophene
hexabenzocoronene 2 (Fig. 3, solid line) reveals three fully
reversible oxidations leading to cation formation with E_1/2
=
+0.38, +0.56 and +1.01 V vs. Fc/Fc⁺ which closely match
those observed in its dimeric twin 3 (Fig. 3, dashed line)
(E_1/2 = +0.38, +0.59 and +1.04 V).
These compare to just two oxidations at E_1/2 = +0.45 and
+0.88 V in all-carbon hexa-tert-butyl-hexa-peri-hexabenzo-
coronene, reported vs. SCE and converted to Fc/Fc⁺
(conversion SCE to Fc/Fc⁺ is ꢀ0.54 V in chloroform).⁴ The
first oxidation on both 2 and 3 occurs at the same potential
(+0.38 V) indicating that this is positioned on the aromatic
phenyl-based platforms and as such is unaffected upon
dimerisation. This first oxidation is at a slightly lower potential
than that seen for the all carbon analogue (+0.45 V) as a
result of the increased electron density due to the presence of
sulfur in the thiophene graphenes. The second and third, fully
reversible oxidation processes (one of which is missing from
the all-carbon hexabenzocoronene) are more influenced by the
Despite the presence of sulfur heteroatoms, the emission
spectrum of 2 closely matches that of alkyl substituted HBCs.⁷
It is very structured (l_max 475 and 505 nm are the most intense
peaks, chloroform, 10^ꢀ3 M) and remains unchanged in shape
and position when different excitation wavelengths and
concentrations (range 10^ꢀ3–10^ꢀ5 M) are employed (Fig. 5).⁸ This
is similar to other HBC systems in which the overall complexity
of the fluorescence spectrum suggests that there are several singlet
excited states that are close in energetic proximity, each having its
own vibronic progression and contributing to the fluorescence.
Fig. 3 Cyclic voltammograms of 2 (solid line) and its dimer 3 (dashed
line) vs. Fc/Fc⁺ (chloroform, 10^ꢀ2 M).
Fig. 5 Normalised excitation (. . .l_em 540 nm) and emission
(—l_exc 367 nm) spectra of 2 (chloroform, 10^ꢀ3 M) at 298 K.
c
This journal is The Royal Society of Chemistry 2011
Chem. Commun., 2011, 47, 3616–3618 3617

View Article Online
Dual luminescence can be dependent on the polarity of
the solvent or related to temperature dependent excimeric
processes.¹² In our case, an excimeric species forms only for
the dimeric system 3 and is not observed for the monomeric
compound 2. Although dual luminescence related to the
twisting of monomeric aromatic subunits has been described
previously in the literature,^11,12 this is the first time in which
the solubility allows exploration of the conformational
consequences of attaching two HBC platforms via a single
carbon–carbon bond. The low luminescence quantum yields
of 2 and 3 (0.024 and 0.011, respectively, in oxygen) are
consistent with other fused polyaromatic systems.¹³ The quan-
tum yields increase in an argon atmosphere, as oxygen quenching
of triplet excited states is prevented (Table S2, ESIw).
The reactivity of the thienyl-polyphenylene precursor 1 has
led to the preparation of two sulfur-containing hexabenzo-
coronene derivatives. The new thienyl-hexabenzocoronene 2
and its dimer 3 resemble all-carbon analogues with photo-
chemical and electrochemical properties similar to those
reported in the literature for hexa alkyl-substituted coronenes.
However dimeric species 3 also has optical properties which
vary with concentration as a result of the orientation of the
two HBC platforms about the newly formed dimer bond. This
luminescence variation is new to HBC-based systems.
Fig. 6 UV/Vis absorption (—10^ꢀ3 M) and excitation spectra of 3 at
high (—10^ꢀ3 M) and low (—10^ꢀ5 M) concentrations (chloroform 298 K).
The emission is biexponential. This is unusual but has been
observed for HBC derived fluorescence in a family of
platinum–HBC acetylides.⁹ The lifetimes vary depending on
the excitation and emission wavelength (Table S3, ESIw). The
excited state lifetime for the emission at 476 and 504 nm is
short lived (both components in the ns range); while at
580 nm, the emission is composed of both a short fluorescence-
derived (12 ns (32%)) and a significantly longer-lived (374 ns
(68%)) component. This suggests the onset of a longer
lived emissive excited state at longer wavelengths which we
tentatively assign as a weak triplet emission, an assignment
corroborated by the appearance of a new broad emission band
at 77 K between 610 and 700 nm (l_max 634 nm) (Fig. S1, ESIw).
The dimeric system 3 exhibits dual luminescence that varies
with concentration. In dilute solution (chloroform, 10^ꢀ5 M)
(Fig. 6), the excitation spectra correspond to the absorption
spectra but with the absence of the low-energy absorption
shoulder for which a planar conformation was responsible
(Scheme 2B).¹⁰ At higher concentration (chloroform, 10^ꢀ3 M)
the excitation spectra exhibit a new low-energy band between
l 500 and 550 nm (l_max 527 nm) at similar l to the tail of the
lowest energy absorption band in the UV/Vis spectrum. This
suggests that a planar conformation (Scheme 2B) is observed
in concentrated solution.
Notes and references
1 L. N. Lucas, J. J. D de Jong, J. H. van Esch, R. M. Kellogg and
B. L. Feringa, Eur. J. Org. Chem., 2003, 155–166; J. H. Hou,
Z. Tan, Y. J. He, C. H. Yang and Y. F. Li, Macromolecules, 2006,
39, 4657–4662; R. D. McCullough, Adv. Mater., 1998, 10, 93–116;
J. Roncali, Chem. Rev., 1997, 97, 173–205.
2 X. L. Feng, J. S. Wu, M. Ai, W. Pisula, L. J. Zhi, J. P. Rabe and
K. Mullen, Angew. Chem., Int. Ed., 2007, 46, 3033–3036.
3 D. J. Gregg, E. Bothe, P. Hofer, P. Passaniti and S. M. Draper,
¨
Inorg. Chem., 2005, 44, 5654–5660; D. J. Gregg, C. M.
A. Ollagnier, C. M. Fitchett and S. M. Draper, Chem.–Eur. J.,
2006, 12, 3043–3052; R. D. J. Roberts, D. J. Gregg, C. M. Fitchett
and S. M. Draper, Organometallics, 2010, 29, 6541–6547.
4 P. T. Herwig, V. Enkelmann, O. Schmelz and K. Mullen,
Chem.–Eur. J., 2000, 6, 1834–1839.
5 W. Hendel, Z. H. Khan and W. Schmidt, Tetrahedron, 1986, 42,
1127–1134.
6 E. Clar, The Aromatic Sextet, John Wiley and Sons, 1972.
7 J. S. Wu, M. D. Watson, L. Zhang, Z. H. Wang and K. Mullen,
J. Am. Chem. Soc., 2004, 126, 177–186.
8 S. Ito, P. T. Herwig, T. Bohme, J. P. Rabe, W. Rettig and K. Mullen,
J. Am. Chem. Soc., 2000, 122, 7698–7706; J. S. Wu, A. Fechtenkotter,
J. Gauss, M. D. Watson, M. Kastler, C. Fechtenkotter, M. Wagner
and K. Mullen, J. Am. Chem. Soc., 2004, 126, 11311–11321;
M. Biasutti, J. Rommens, A. Vaes, S. DeFeyter, F. de Schryver,
P. Herwig and K. Mullen, Bull. Soc. Chim. Belg., 1997, 106, 659–664.
At low concentration the emission of 3 (Fig. 7) shows
structured high-energy bands similar in position to the emis-
sion observed for the monomer 2 between l 450 and 550 nm
(l_max 494 nm) and a second broader lower-energy emission
between l 550 and 675 nm (l_max 565 nm). In more concen-
trated solutions (chloroform, 10^ꢀ3 M) this broad low-energy
emission (Fig. 7) dominates (l_max 580 nm), suggesting that a
planar conformation is observed in concentrated solutions
that gives rise to excited state aggregates and the formation
of excimeric species.¹¹
9 K. Y. Kim, S. Liu, M. E. Kose and K. S. Schanze, Inorg. Chem.,
2006, 45, 2509–2519.
¨
10 X. N. Zhang, M. Kohler and A. J. Matzger, Macromolecules, 2004,
37, 6306–6315; N. DiCesare, M. Belletete, A. Donat-Bouillud,
M. Leclerc and G. Durocher, Macromolecules, 1998, 31,
6289–6296; N. DiCesare, M. Belletete, F. Raymond, M. Leclerc
and G. Durocher, J. Phys. Chem. A, 1997, 101, 776–782; S. A. Lee,
S. Hotta and F. Nakanishi, J. Phys. Chem. A, 2000, 104, 1827–1833.
11 Q. Yan, Y. Zhou, B. B. Ni, Y. G. Ma, J. Wang, J. Pei and Y. Cao,
J. Org. Chem., 2008, 73, 5328–5339; N. DiCesare, M. Belletete,
E. R. Garcia, M. Leclerc and G. Durocher, J. Phys. Chem. A, 1999,
103, 3864–3875.
12 Z. R. Grabowski, K. Rotkiewicz and W. Rettig, Chem. Rev., 2003,
103, 3899–4032.
13 Y. S. Liu, P. Mayo and W. R. Ware, J. Phys. Chem., 1993, 97,
5595–6001.
Fig. 7 UV/Vis absorption (—10^ꢀ3 M) and emission spectra of 3 at high
(—10^ꢀ3 M) and low (—10^ꢀ5 M) concentrations (chloroform) at 298 K.
c
3618 Chem. Commun., 2011, 47, 3616–3618
This journal is The Royal Society of Chemistry 2011