Chemical
Science

EDGE ARTICLE
Dimeric tetrabro
aDepartamento de Qúımica Orgánica, Facu

Complutense de Madrid, 28040 Madrid

nazmar@quim.ucm.es
bInstituto de Ciencia Molecular, Universid

E-mail: enrique.orti@uv.es
cDepartamento de Qúımica F́ısica, Universi
E-mail: casado@uma.es
dIMDEA-Nanociencia, C/ Faraday, 9, Campu

E-mail: david.ecija@imdea.org

† Electronic supplementary informa
https://doi.org/10.1039/d3sc01615c

‡ These authors contributed equally to th

Cite this: Chem. Sci., 2023, 14, 10112

All publication charges for this article
have been paid for by the Royal Society
of Chemistry

Received 28th March 2023
Accepted 9th August 2023

DOI: 10.1039/d3sc01615c

rsc.li/chemical-science

10112 | Chem. Sci., 2023, 14, 10112–10
mo-p-quinodimethanes: synthesis
and structural/electronic properties†

Diego J. Vicent, ‡a Manuel Pérez-Escribano, ‡b Abel Cárdenas-Valdivia,c

Ana Barragán, d Joaqúın Calbo, b José I. Urgel, d David Écija, *d

José Santos, *a Juan Casado, *c Enrique Ort́ı *b and Nazario Mart́ın *ad

Despite their great potential as molecular building blocks for organic synthesis, tetrabromo-p-

quinodimethanes (TBQs) are a relatively unknown family of compounds. Herein, we showcase a series of

five derivatives incorporating two tetrabromo-anthraquinodimethane (TBAQ) units linked by p-

conjugated spacers of different nature and length. The resulting dimers TBQ1–5 are fully characterised

by means of thorough spectroscopic measurements and theoretical calculations. Interestingly, owing to

the steric hindrance imposed by the four bulky bromine atoms, the TBAQ fragments adopt

a characteristically warped geometry, somehow resemblant of a butterfly, and the novel dimers show

a complex NMR pattern with signal splittings. To ascertain whether dynamic processes regarding

fluxional inversion of the butterfly configurations are involved, first-principles calculations assessing the

interconversion energy barriers are performed. Three possible stereoisomers are predicted involving two

diastereomers, thus accounting for the observed NMR spectra. The rotational freedom of the TBAQ units

around the p-conjugated linker influences the structural and electronic properties of TBQ1–5 and

modulates the electronic communication between the terminal TBAQ moieties. The role of the linker on

the electronic properties is investigated by Raman and UV-vis spectroscopies, theoretical calculations

and UV-vis measurements at low temperature. TBQ1–5 are of interest as less-explored structural

building precursors for a variety of scientific areas. Finally, the sublimation, self-assembly and reactivity

on Au(111) of TBQ3 is assessed.
Introduction

Bottom-up synthetic approaches for preparing complex organic
structures can be highly time and resources consuming. Thus,
organic chemists tend to make use of pre-made molecular
fragments, modularly assembling them into more complex
structures. These so-called molecular building blocks are
usually endowed with different reactive functional groups sup-
ported onto a scaffold of low-to-medium complexity. The use of
appropriate building blocks, therefore, allows speeding up the
synthetic tasks as well as decreasing the synthetic costs.
ltad de Ciencias Qúımicas, Universidad

, Spain. E-mail: jsantosb@pdi.ucm.es;

ad de Valencia, 46980 Paterna, Spain.

dad de Málaga, 229071 Malaga, Spain.

s de Cantoblanco, 28049 Madrid, Spain.

tion (ESI) available. See DOI:

e work.

120
Molecules bearing gem-dibromoolene functionalities have
been employed as intermediates in the well-known Ramirez–
Corey–Fuchs homologation of carbonyls to alkynes.1,2 They are
readily attained from either ketones or aldehydes by reacting
with carbon tetrabromide and triphenylphosphine. Upon lith-
iation, gem-dibromoolenes undergo Fritsch–Buttenberg–Wie-
chell (FBW) rearrangement to yield the corresponding alkyne.3,4

Besides their use in FBW rearrangements, this functionality has
found use in the synthesis of [4]radialene.5 Nonetheless, it is as
substrates for palladium cross-coupling reactions where gem-
dibromoolenes have found a broader use, allowing Suzuki,6

Stille7 and Sonogashira couplings.8 When the gem-dibromoole-
nes are stemming from p-quinones, the resulting tetrabromo-
p-quinodimethanes (TBQs) may undergo dehalogenative
homocoupling on coinage metal surfaces, namely Au(111) and
Ag(111), forming one-dimensional (1D) acene and periacene
polymers that may exhibit appealing non-trivial topological
electronic properties, depending upon the acene nature and
length of the polymer.9–13

As building blocks bearing four reactive bromine atoms,
TBQs are excellent platforms for the incorporation of up to four
substituents. This high degree of functionalisation is ideal for
some organic electronics applications, as in the case of hole
© 2023 The Author(s). Published by the Royal Society of Chemistry

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https://doi.org/10.1039/d3sc01615c


Edge Article Chemical Science
transporting materials (HTMs) for perovskite solar cells (PSCs),
where the presence of several electroactive arylamine groups
strongly enhances the charge transport. For instance, when
triarylamine functionalities are inserted into an anthraquinone-
based TBQ (TBAQ), the resulting HTM exhibits high photovol-
taic performance and stability in large area PSCs.14 The steric
hindrance of the anthracene peri hydrogens allows conceiving
molecules with switchable geometry, which makes TBQs ideal
platforms for synthetising materials with aggregation-induced
emission (AIE) and photochromism properties.15–17 If the core
of the TBQ is a pentacene, then the substitution with phenyl
derivatives yields a structure that is prone to undergo a cyclo-
dehydrogenation reaction to provide hexabenzocoronenes,
which have potential as semiconducting materials for eld-
effect transistor applications.18 Another example of their
potential in materials science is found in molecules with self-
assembly capabilities.19

Regarding their chemical structure, TBQ building blocks can
be considered as precursors for the synthesis of p-extended
analogues of Thiele's and Chichibabin's hydrocarbons. Owing
to their quinoid character, they have a strong tendency to sta-
bilise open-shell chemical structures when suitably
substituted.20,21 For example, the deposition of a bipentacene
TBQ on a Au(111) surface allowed the synthesis of peri-
pentacene and the unequivocal characterization of its open-
shell character.22

The versatility of the TBQ functionality as building block for
preparing a wide variety of molecules of high interest in mate-
rials science and organic electronics prompted us to design,
synthesise and expand the spectrum of TBQ derivatives by
preparing a series of anthracene-based TBQ dimers (Scheme 1).
The newly synthesised TBQ1–5 molecules are endowed with
eight bromine atoms located on the two anthra-p-quinodi-
methane units which are, in turn, covalently connected by
different spacers that modulate the conjugation and/or elec-
tronic communication between them. The structural, elec-
tronic, optical and vibrational experimental properties of the
TBAQ building block and of the TBQ dimers were jointly studied
Scheme 1 Synthetic route to the dimeric tetrabromo-p-quinodimethan

© 2023 The Author(s). Published by the Royal Society of Chemistry
with rst-principles calculations and spectroscopic techniques
to deepen into the understanding of their intramolecular
characteristics. Furthermore, the sublimation, self-assembly
and reactivity of a TBQ archetype (TBQ3) was explored on
Au(111). Altogether, our ndings could eventually seed supra-
molecular and material properties based on these high-
bromine functional molecules.
Results and discussion
Synthesis and structural properties

The synthesis of TBQ-based building blocks can be achieved
starting from relatively unexpensive products (Scheme 1).
Reaction of 4,4′-oxydiphthalic anhydride (1) with AlCl3 in
benzene, followed by treatment of the resulting product with
polyphosphoric acid (PPA) provides anthraquinone dimer 2 in
good yield.23 To obtain TBQ1, standard Ramirez olenation
conditions employing CBr4 and PPh3 were applied,1 although
the yields were low to moderate. On the other hand, to syn-
thesise TBQ2–5 the key starting material was 2-bromoan-
thraquinone (3), which may be purchased from commercial
retailers or readily attained from bromobenzene and phthalic
anhydride. Product TBQ2 is obtained starting from 3 in two
steps. First step involves the one-pot two-fold Sonogashira
cross-coupling of trimethylsilylacetylene with two molecules of
3, enabled by the use of 1,8-diazabicyclo[5.4.0]undec-7-ene
(DBU) as base, with moderate yield. When the resulting
acetylene-bridged anthraquinone dimer (4) is exposed to stan-
dard Ramirez olenation conditions, inseparable complex
reaction mixtures were obtained. The study of the crudes by
mass spectroscopy revealed peaks with isotopic proles
compatible with molecules carrying various bromine atoms.
Following a previous study by M. Lauten and coworkers,24 where
phosphites demonstrated enhanced reactivity towards ketones
compared to phosphines, tri-iso-propylphosphite [P(OiPr)3] was
employed. Use of 2 and 4 equivalents of CBr4 and P(OiPr)3,
respectively, per carbonyl equivalent, led to partial olenation
products of 4, although no complex mixtures were observed.
es TBQ1–5.

Chem. Sci., 2023, 14, 10112–10120 | 10113



Fig. 1 Relative electronic energy (a) and molecular structure (b) of the
different conformations localized at the BMK/6-31G(d,p) level on the
potential energy surface of TBAQ. In (a), the number of imaginary
frequencies of each structure is indicated within parentheses, and the
arrows indicate the evolution of the structure upon deformation along
the imaginary modes. In (b), side (left) and top (right) views are dis-
played. Color coding: H in white, C in gray and Br in yellow.

Chemical Science Edge Article
Full conversion of the starting material to TBQ2 was nally
achieved by adding three extra loads of CBr4 and P(OiPr)3.

To synthesise TBQ5 from precursor 6, featuring a butadiyne
bridge, 2-ethynylanthraquinone was quantitatively homo-
coupled via Hay coupling. For preparing TBQ4 from precursor
7, the starting material 3 was coupled with 1,4-dieth-
ynylbenzene by Sonogashira reaction. Finally, precursor 8 used
to obtain TBQ3 was prepared by Suzuki reaction of 3 with 1,4-
bis(4,4,5,5-tetramethyl-1,3,2-dioxaborolan-2-yl)benzene. Final
products TBQ3–5 were obtained following the same procedure
as for TBQ2 (Scheme 1). The FTIR spectra of TBQ1–5 evidence
the lack of the characteristic carbonyl band of the precursing
quinones, along with the arising of an intense sharp band at ca.
760 cm−1 ascribed to the out-of-plane bending of the C]CBr2
moieties. Featuring eight bromine atoms per molecule, TBQ1–5
show a very characteristic isotopic prole (see Fig. S13–S19†).

Prior to theoretically characterizing the high-bromine TBQ1–
5 dimers, the structure of the TBAQ building block was
inspected and compared with that computed for the widely
studied cyano-based tetracyanoanthra-p-quinodimethane
(TCAQ) analogue. Geometry optimizations were performed
within the density functional theory (DFT) framework at the
BMK/6-31G(d,p) level of theory in gas phase (see the Compu-
tational methods section in the ESI† for full computational
details and methodology benchmark). In the case of TCAQ, the
fully planar D2h conformation is a high-order saddle point with
four imaginary vibrational modes (see Section S6 in the
ESI†).25–27 When considering TBAQ, the D2h conformation
shows up to ve imaginary vibrational frequencies (Section
S7†). Starting from this planar structure, the search for the
global minimum-energy conformer was performed by distorting
the molecular geometry along the imaginary vibrational modes
with symmetry constraints (Fig. 1). Three conformations, two of
them equivalent to each other and possessing a C2h point group
of symmetry (C0

2h and C*
2h), and the D2 conformation, are

transition states and a high-order saddle point, respectively,
that further present one or two imaginary frequencies. These
three structures are calculated ca. 20 kcal mol−1 more stable
than the planar D2h molecular geometry. From the D2 confor-
mation, a local minimum-energy, chair-like structure is pre-
dicted with no imaginary frequency and C2h symmetry, which is
computed 31.3 kcal mol−1 more stable than the D2h conformer
(Fig. 1). Finally, the global minimum-energy structure, dis-
playing a saddle- or buttery-like disposition, belongs to the C2v

point group of symmetry, and is calculated 53.8 kcal mol−1

lower in energy than the planar D2h structure. Noticeably, the
buttery inversion through D2h is highly unfavorable for TBAQ
(53.8 kcal mol−1) compared to TCAQ (22.3 kcal mol−1).
However, as the intermediate transition states (C0

2h, C*
2h and D2)

connect with the C2v global minimum, the buttery shape of
TBAQ can be inverted with an activation barrier of
33.3 kcal mol−1, to be compared with a value of 18.4 kcal mol−1

for TCAQ. Nonetheless, the buttery interconversion process is
still signicantly impeded at room temperature.

To gain insight into the structural changes driving the rela-
tive energy difference between the C2v global minimum-energy
structure and the planar D2h transition state for TBAQ in
10114 | Chem. Sci., 2023, 14, 10112–10120
comparison to TCAQ, we investigated the two main structural
deformations that follow the interconversion from D2h to C2v;
i.e., the planar-to-buttery change and the widening of the Br–
C–Br and NC–C–CN bond angles (see Section S8† for details).
Theoretical calculations at the BMK/6-31G(d,p) level indicate
that the change from planar to buttery shape, in going from
D2h to C2v, leads to a net stabilization of −37.4 and −10.7 kcal-
mol−1 for TBAQ and TCAQ, respectively. The larger stabilization
observed for TBAQ is consistent with the presence of the bulkier
Br atoms, compared to the cyano groups of TCAQ, as the elec-
tron localization function evidences (Fig. S25†).28 In line with
the previous reasoning, in TBAQ the broadening of the Br–C–Br
angle from 98° in D2h to 124° in C2v provides a larger stabili-
zation (−16.1 kcal mol−1) than the relaxation of the NC–C–CN
angle of TCAQ (from 97° in D2h to 111° in C2v with a stabiliza-
tion of −11.1 kcal mol−1), thus supporting the larger steric
interactions between Br atoms.

The 1H and 13C magnetic resonances of the TBQ1–5 dimers
reveal interesting structural aspects of these molecular systems
(Fig. S3–S12†). Considering the substitution pattern of the
phenyl rings through which the anthracenes are linked by
(Scheme 1), the 1H-NMR spectra should show three sets of
© 2023 The Author(s). Published by the Royal Society of Chemistry



Fig. 3 Rotational energy barrier profile calculated for TBQ2 at the
BMK/6-31(d,p)+PCM(CH2Cl2) level along the torsion of the dihedral
angle q (in red) defining the relative orientation of the TBAQ moieties.

Edge Article Chemical Science
signals integrating for one proton each: the lone peri proton
(position C1) showing as a doublet, coupled with a small 4J
coupling constant to the proton in meta (position C3); the latter
appearing as a double doublet due to the coupling with the
proton in ortho to it (position C4); this last proton showing itself
as a doublet. Instead, some of these signals split in some of the
TBQs, i.e., H–C1 and H–C3 of TBQ1 (Fig. S3†) and TBQ2 (Fig. 2).
In the case of these dimers bearing shorter linkers, the prox-
imity of both TBAQ subunits seems to create different magnetic
environments for the above-mentioned protons. As larger
spacers are introduced, e.g. in TBQ5, the splitting effect tends to
vanish, as both TBAQs stop magnetically affecting each other
(see Fig. 2). The splitting effect is also observed in the case of the
13C-NMR signals, mainly concerning the signal of the carbon
nuclei involved in the alkyne fragment and the ones close to it
(C1, C2 and C3) (see Fig. S4, S6 and S9†).

In order to assess the possibility of having rotamers with
different buttery-to-buttery relative orientations (same vs.
opposite orientation with respect to the molecular plane) that
may explain the NMR signal splitting described above, the
energy barrier for single-bond TBAQ rotation was evaluated for
TBQ1–5 dimers at the BMK/6-31G(d,p) level including solvent
conditions (CH2Cl2) (see Section S9 of the ESI† for further
details). Fig. 3 displays the rotational barrier prole calculated
for TBQ2 as a representative example (see Fig. S26–S29† for the
other dimers). Theoretical calculations indicate that the
buttery rotation along dihedral angle q is accessible at room
temperature, as torsion barriers in the range of 0.31–
3.47 kcal mol−1 are predicted for the highly containing bromine
dimers (Table S2†). The largest energy barriers are predicted for
TBQ1 and TBQ3 due to the evident H/H steric hindrance upon
rotation. Analysis of the Br/H–C1 distance (Fig. S30†) conrms
a signicant change in length upon buttery rotation (Table
S3†). This distance is signicantly shorter for TBQ1 and TBQ2,
achieving minimum values of 5.12 and 6.17 Å, respectively,
which could explain the 1H-NMR signal splitting recorded
experimentally for the H–C1 peri proton in these derivatives
bearing shorter linkers (Fig. 2).

A detailed analysis of the possible congurational isomers of
TBQ2 (Fig. S1†) reveals the presence of three possible isomers,
Fig. 2 Comparison of the 1H-NMR spectra of TBQ2 and TBQ5
showing the splitting of the peri hydrogen signal of the former,
consistent with the presence of two isomeric species.

© 2023 The Author(s). Published by the Royal Society of Chemistry
i.e., a pair of enantiomers and a meso form. Attempts to isolate
the diastereomers by chromatographic means were to no avail
due to the limited solubility of TBQ2 in the eluting mixture and
the negligible chromatographic separation between diastereo-
mers. However, 1H-NMR spectra of the collected fractions show
diminished intensity for one of the doublets constituting the
split signal of the H–C1 peri proton (see Fig. S12†), as would be
expected from a fraction enriched in one of the diastereomers.

Vibrational spectroscopic properties

The solid-state Raman spectra of the TBQ dimers together with
that recorded for TBAQ are shown in Fig. 4a. The BMK/6-
31G(d,p) Raman spectrum simulated for TBQ2 compares very
well with the experimental spectrum in the whole spectral
region, as may be observed in Fig. S63,† allowing to make
a vibrational assignment of the experimental bands in terms of
the main components of the vibrational normal modes (Fig. S64
and S65†). The experimental bands of TBQ2 at 1601 and
1593 cm−1 can be correlated with the theoretical bands at 1593
and 1579 cm−1, respectively. The two modes are composed by
the C]C stretching modes [n(C]C)] of the anthraquinone core
with CC displacements featuring the breathing mode of the six-
member rings (i.e., vibrational normal modes 1 and 3 of
benzene, see Fig. 4b) and coupled with the outermost methy-
lene C]C stretches of the CCBr2 moieties, or n(C]C)mode1-3 +
n(C]CBr2). On the other hand, the experimental bands of TBQ2
at 1582 and 1561 cm−1 correspond to those theoretically pre-
dicted at 1569 and 1553 cm−1, respectively, and can be
described as C]C stretchingmodes carrying out the 8amode of
benzene in which the bonds of the central six-member ring,
which are parallel to the external methylene double bonds,
simultaneously stretch, or n(C]C)mode8 + n(C]CBr2). The BMK/
6-31G(d,p) theoretical Raman spectra calculated for TBAQ at the
C2v, C2h and D2h geometries in Fig. 1 (Fig. S66†) reveals that the
n(C]C) + n(C]CBr2) bands experience a progressive increment
of their wavenumbers upon sequential C2v / C2h / D2h pla-
narization of the central anthracene core.

The experimental vibrational Raman intensity patterns of
TBQ2 and TBAQ in the 1600 cm−1 region are apparently very
similar, the wavenumbers of the corresponding bands showing
Chem. Sci., 2023, 14, 10112–10120 | 10115



Fig. 4 (a) Raman spectra of the compounds in solid state at 298 K,
employing a 785 nm laser (blue-shaded bands are those mainly dis-
cussed in the text). (b) BMK/6-31G(d,p) theoretical vibrational n(CC)
modes (wavenumbers in cm−1) of TBQ2 showing the main CC
displacements and related to the modes 1, 3 and 8a of benzene. (c)
Wavenumber evolution of the n(CC) vibrational modes (mode 1–3 of
benzene) from the TBAQ units (in red) upon vibrational coupling with
the central n(CC) acetylene spacer (in purple) and with the n(CC) of the
single connecting bonds (in yellow). Vibrational splittings are qualita-
tive. (d) Vibrational splitting of the 1–3 and 8a modes simultaneously
from TBAQ to TBQ2. Experimental values are shown in bold (blue-
shaded bands are those equally denoted in the experimental spectra).

Fig. 5 Comparison between the 785 nm solid-state laser Raman
(pointing up) and the infrared (pointing down) spectra of TBAQ (below)
and TBQ2 (above) at 298 K, normalized to the strongest Raman and
infrared bands.

Chemical Science Edge Article
an overall upshi in passing from TBAQ to TBQ2 (Fig. 4a). For
instance, the strongest Raman band at 1586 cm−1 in TBAQ
shis to 1593 cm−1 in TBQ2 (blue-shaded in Fig. 4a). This
strong band keeps slightly upshiing in the dimers, up to by
+3 cm−1 on TBQ2 / TBQ3. There are two possible reasons
behind these wavenumber upshi upon dimerization: (i) the
planarization of the anthracene core, as observed for TBAQ
along C2v / C2h / D2h symmetry transformations (Fig. S66†),
and (ii) the role of the linker in the dynamics and electronic
structure of the TBAQ units upon formation of TBQ2.
Comparison of the optimized minimum-energy geometries
calculated for the TBAQmolecule and the TBAQ subunits within
the dimers indicates a negligible planarization of the buttery
moiety in TBQ1–5, with root-mean-square deviations of the
atomic positions in the dimers with respect to TBAQ smaller
than 0.01 Å and a folding of the anthracene skeleton differing in
only 0.2° (Table S4†). On the other hand, the vibrational
couplings suggested in point (ii) are qualitatively presented in
Fig. 4c and d (and Fig. S64 and S65†), where the evolution of the
n(CC) modes upon assembly and subsequent vibrational mixing
of two TBAQ monomers with a central acetylene (and with two
CC single bonds) is shown. The 1–3 and 8a benzenoid-like
modes of TBAQ are calculated at 1588 and 1580 cm−1, respec-
tively, in good correlation with the Raman peaks observed at
1593 and 1586 cm−1. Interestingly, in the theoretical Raman
spectra of TBAQ and TBQ2, the most active Raman bands
correspond to modes of different vibrational nature, the 8a
10116 | Chem. Sci., 2023, 14, 10112–10120
mode in TBAQ at 1580 cm−1 and the 1–3 mode in TBQ2 at
1579 cm−1. This change in the vibrational structure of the
strongest Raman bands reveals the effect of the dimerization in
the vibrational spectra, which modies the electronic polariz-
ability tensor in such a way that its largest variation between
TBAQ and TBQ2 occurs in different vibrational modes. Elon-
gation of the bridge between the two TBAQ units in compounds
TBQ3–5 slightly modies the vibrational mixing and similar
frequencies are detected in the Raman spectra. Conversely,
vibrational bands of the same nature are found to downshi
upon dimerization, what is in accordance with the common
nding that the Raman wavenumbers always decrease with the
increment of p-conjugation in oligomeric series.29–31

Fig. 5 displays the normalized infrared and Raman spectra of
TBAQ and TBQ2 in the spectral regions where the strongest
bands aremeasured, i.e., around 1600 cm−1 for the n(CC) modes
in the Raman spectrum and at 750 cm−1 for the n(CBr) modes in
the infrared spectrum (theoretically compared in Fig. S67 and
S68†). In general, for the two molecules under comparison and
concerning their vibrational bands in common (i.e., those of
TBAQ), it can be seen that each strong Raman band around
1600 cm−1 has a weak infrared analogue feature. Conversely, in
the region around 750 cm−1, each intense infrared band has
a corresponding weak Raman feature. This reveals that all these
vibrations display non-vanishing infrared and Raman intensi-
ties, which is in agreement with a C2v molecular symmetry in
TBAQ and a local C2v conformation for the TBAQ units in TBQ2
as well. Nonetheless, it is observed in Fig. 5 that every Raman
(infrared) active mode of TBQ2 is much less active in the
infrared (Raman) (dotted lines correlate vibrational modes in
the Raman and infrared spectra) than the corresponding
signals in TBAQ. This observation might be indicative of
a symmetry alteration upon formation of the dimer, whose
molecular structure evolves closer to a form with an inversion
centre around the central acetylene bridge.

Electronic structure and optical properties

The electronic structure of the high-bromine dimers TBQ1–5
was studied at the DFT-BMK/6-31G(d,p) level in
© 2023 The Author(s). Published by the Royal Society of Chemistry



Edge Article Chemical Science
dichloromethane. Theoretical calculations indicate that the
highest-occupied molecular orbital (HOMO) is mainly delo-
calized over the bridge and the inner benzene ring of the
anthraquinone moieties (see Fig. S31†). Similarly, the lowest-
unoccupied molecular orbital (LUMO) is centred over the
bridge and extends to the TBAQ moieties, especially for the less
conjugated TBQ1 and TBQ3 derivatives. Increasing the p-
conjugation of the bridge leads to a systematic destabilization
of the HOMO level from −6.81 eV in TBQ1 to −6.43 eV in TBQ4,
whereas the LUMO lowers in energy from −1.34 eV in TBQ1 to
−1.82 eV in TBQ5 (Table S5†). As a result, the HOMO–LUMO
energy gap varies in a range of values from 5.47 eV for TBQ1 to
4.69 eV for TBQ4, suggesting a strong shi in the optical
properties along the family of TBQ dimers (see below).

The large destabilization of the LUMO of TBAQ (−1.18 eV)
and TBQ dimers (from −1.34 to −1.82 eV, Table S5†) compared
to TCAQ (−3.49 eV) remarks that the reduction of the TBAQ
moiety is signicantly hindered compared to TCAQ. As
a consequence, TBQ1–5 show no reduction activity in the cyclic
voltammetry experiments performed within the solvent scan
window. It is noteworthy, that exocyclic bromovinylenes are
prone to decomposition via debromination, thus limiting the
experimental characterization of their redox properties.

The experimental optical characterisation of TBQ1–5 is
summarized in Fig. 6. All TBQ dimers present absorption
features in the UV region between 250 and 370 nm. The lowest
energy absorption of TBQ1 (300 nm) and TBQ3 (314 nm) is blue
shied compared to the other TBQs, due to the restricted
conjugation imposed by their oxygen and phenyl linkers. When
an alkyne linker is introduced in TBQ2, extension of the
conjugation effect is evidenced by a red shi of the absorption
(349 nm). Increasing the length of the p-conjugated bridge
leads to lower-energy absorptions in TBQ4 and TBQ5 (368 and
365 nm, respectively). Interestingly, the dimers with alkyne
spacers (TBQ2 and TBQ5) show similar absorption proles
featuring four bands, the most energetic two lying at ca. 263 and
315 nm, and the lower-energy ones peaking at 325 and 349 nm
for TBQ2 and 339 and 365 nm for TBQ5. All TBQ derivatives
exhibit weak emission features in non-deaerated solutions, with
small Stokes shis of about 10 nm for TBQ2, TBQ4 and TBQ5,
and 30 and 55 nm for TBQ1 and TBQ3, respectively.
Fig. 6 Optical properties of TBQ1–5 in CH2Cl2 solution at 25 °C. The
blue plot corresponding to the normalised absorption and the orange
to the normalised emission.

© 2023 The Author(s). Published by the Royal Society of Chemistry
Theoretical calculations were performed by means of the
time-dependent DFT (TD-DFT) approach to unveil the nature of
the low-lying absorption bands for TBQ1–5. The lowest-energy
absorption band experimentally recorded at 300–365 nm
results from the electronic transition to the rst singlet excited
state S1 (Fig. S33–S37†), except for TBQ1, for which the transi-
tion to the S2 state is predicted near S1 and also contributes to
this band with an oscillator strength (f) of 0.551 (Fig. S33†). The
S0 / S1 transition mostly originates in the HOMO / LUMO
monoexcitation (Table S6†), and, according to the topology of
these orbitals, is described by a local excitation mainly centred
in the linker and the inner anthraquinone halves. The elec-
tronic nature of the S1 excitation is conrmed by the natural
transition orbitals involved in the transition (Fig. S38–S42†),32

which suggest a small charge-transfer from the linker to the
TBAQ moieties, especially for the less-conjugated TBQ1 and
TBQ3 derivatives.

The effect of the internal rotation of the TBAQ units on the
rst singlet excited states was disclosed to better understand
the complex low-lying absorption pattern with several peaks
recorded for TBQ2 and TBQ5 (Section S13†). TD-DFT calcula-
tions indicate that the torsion of the TBAQ moiety along q

signicantly shis the S1 excitation energy, e.g., from 335 nm at
q = 0° to 300 nm at q = 100° for TBQ2 (Fig. S43†). The torsion
also impacts on the position and intensity of higher-energy
states as predicted for the excited states S2 and S4 of TBQ5 at
intermediate rotation angles (q = 80–100°, Fig. S45†). These
results highlight that the position of the absorption peaks
recorded experimentally and the shape of the absorption
spectra, especially in TBQ2 and TBQ5, might come from the
large rotational freedom of these TBQ dimers.

The study of the evolution of the absorption features of TBQ2
as a function of the temperature on cooling (Fig. 7) reveals
progressive spectral changes that mainly involve: (i) the red-
shi of the absorption features, which is characteristic of p-
conjugated chromophores, and (ii) a hyperchromic shi of the
lowest-energy bands of the spectrum (i.e., the band at 349 nm
red shis to 355 nm and becomes the strongest of the spectrum
at 80 K). In addition, the resolution of new vibronic bands is
observed, such as the 333/339 nm pair. This temperature-
dependent behaviour is typically found in exible p-
Fig. 7 Variable-temperature UV-vis electronic absorption spectra of
TBQ2 in 2-methyltetrahydrofurane upon cooling from 298 K to 80 K.
The dotted grey line corresponds to the spectrum recorded at room
temperature after cooling.

Chem. Sci., 2023, 14, 10112–10120 | 10117



Chemical Science Edge Article
conjugated compounds, in which the blockade of the torsional
vibrational motions produces a greater population of more
planar conformers in detriment of the more distorted ones.33

These conformationally frozen structures give way to the
vibronic resolution and consequently the 0–0 vibronic bands
become the most active bands of the spectrum.

The variable-temperature UV-vis experimental data are nicely
supported by the rotational energy barriers obtained from
quantum-chemical calculations. The predicted maximal energy
barriers of ca. 1 kcal mol−1 for TBQ2 are assimilable to the
amount of thermal energy removed on cooling from 298 to 80 K
(i.e., 0.43 kcal mol−1). These results highlight that at room
temperature the molecule has free rotation, with a broad set of
thermally populated rotational conformers, whereas the rota-
tion barrier becomes harder to overcome as the temperature
diminishes. Therefore, only the most stable planar conformers
are present at low temperature, and give rise to the vibronically-
resolved UV-vis spectrum at 80 K.

Self-assembly and reactivity on Au(111)

Finally, we have explored the capabilities of TBQs to steer
molecular architectures on surfaces. To this aim, we deposited
a submonolayer coverage of TBQ3 on a pristine Au(111) surface
kept at room temperature. As illustrated in Fig. 8a, aer such
deposition, a disordered molecular assembly is found, where
characteristic bright protrusions coming in pairs are detected
coexisting with irregular darker features. By a proper compar-
ison with previous ndings from our group, it is feasible to
rationalize such molecular assembly.9 TBQ3 can be interpreted
as two TBAQ units connected by a phenyl bridge. The deposition
of TBAQ on Au(111) leads to a regular self-assembly in which the
molecular species are intact, displaying a buttery
Fig. 8 On-surface deposition and reactivity of TBQ3 species on
Au(111). (a) Overview STM image of the sublimation of a submonolayer
coverage of TBQ3 on a pristine Au(111) surface kept at room
temperature. Vb= 1 V, It= 100 pA, scale bar: 4.0 nm. (b) Left: Zoomed-
in image of the blue rectangle indicated in panel (a) showing an intact
molecule with two consecutive pairs of elongated bright protrusions.
Right: Superposition of the chemical model. (c) Long-range STM
image after the annealing of (a) at 150 °C. Vb = 0.5 V, It = 50 pA, scale
bar: 4 nm. (d) Left: Zoomed-in image of the green highlighted area in
panel (c). Right: Superposition of the chemical model.

10118 | Chem. Sci., 2023, 14, 10112–10120
conformation and exhibiting two distinct adsorption geome-
tries: either the phenyl moieties pointing up (observed in STM
as two elongated bright protrusions) or down.9 Similar results
are visualized for the assembly of TBQ3 on Au(111), though
some of them appear in pairs. Thus, we rationalize that upon
sublimation over 80% of TBQ3 molecules cleave by the phenyl
bridge, therefore TBAQ fragments coexist with pristine TBQ3 on
the surface. Importantly, adsorbed pristine TBQ3 species (10–
20%) are visualized as two consecutive pairs of two elongated
protrusions, as illustrated in Fig. 8b.

Next, such molecular assembly was annealed to steer
debromination and homocoupling reactions (Fig. 8c). We
observed the formation of molecular wires, many of them cor-
responding to polymers arising from the homocoupling of
debrominated TBAQ fragments. Notably, the surviving TBQ3
species, from the sublimation and adsorption at room
temperature, have been able to react upon annealing, giving rise
to segments of conjugated ladder polymers, as illustrated in
Fig. 8d, though featuring frequent side reactivity due to
concomitant intra- and inter-molecular reactions.

Conclusion

In summary, ve novel dimeric molecules (TBQ1–5) based on
the tetrabromoanthra-p-quinodimethane (TBAQ) motif have
been synthesized. Owing to their high bromine content nature,
these systems are excellent platforms for preparing more
complex, highly substituted derivatives, which makes them very
appealing and versatile building blocks. Theoretical DFT
calculations reveal that the experimentally observed NMR signal
splitting neither arise from slow rotation of the TBAQ moieties
along the separating linker, nor from the uxional inversion of
the buttery conguration of the TBAQ core. Featuring activa-
tion barriers in the 0.3–3.5 kcal mol−1 range for bond rotation,
TBQ1–5 dimers can freely rotate at room temperature. On the
other side, the high energy barriers predicted for the uxional
inversion of the buttery conguration makes it unaffordable at
low-to-moderate temperatures. Considering the characteristic
buttery geometry of the TBAQ subunits, when two such units
are chemically bound, three possible stereoisomers involving
a pair of enantiomers and a meso form are produced, thus
explaining the observed NMR splitting. Interestingly, the
Raman shis to higher frequencies of the vibrational modes of
TBQ1–5 when increasing the length of the bridges linking the
TBAQ moieties, point to an enhanced p-electron delocalization
of the buttery conguration of the TBAQs, which is further
evidenced in the electronic and optical properties. The modu-
lation of such p-conjugation, even in small amounts, is a key
aspect in the design of molecular building blocks and precur-
sors given the enhancement or multiplicative effects these
might have in the electronic structure of the nal targeted
products.

The preliminary on-surface chemistry study demonstrates
the capabilities of TBQ species to be sublimated, adsorbed and
homocoupled on surfaces, though still further research efforts
are necessary to improve the sublimation and to promote the
formation of regular polymers.
© 2023 The Author(s). Published by the Royal Society of Chemistry



Edge Article Chemical Science
The results here reported unveil the structural, spectroscopic
and electronic properties of these less-known but useful TBAQ-
based building blocks and pave the way to a better under-
standing for the variety of further potential derivatives of
interest in different scientic areas. Work is currently in prog-
ress in this regard.
Data availability

The BMK/6-31G(d,p)(PCM)-optimized structures calculated for
TBAQ, TCAQ and TBQ1-5 are available at the ZENODO reposi-
tory (https://doi.org/10.5281/zenodo.8038098). Computational
results and structures can also be retrieved from the authors
upon request.
Author contributions

N. M. and J. S. conceived the project. D. J. V., M. P.-E., A. C. V.,
and A. B. performed the investigation. J. S., M. P.-E., A. B., J. I.
U., D. E., and J. C. analysed the results. J. S., M. P.-E, and J. C.
wrote the manuscript. All authors reviewed and edited the
manuscript. N. M., E. O. and J. C. supervised the project.
Conflicts of interest

There are no conicts of interest to declare.
Acknowledgements

Financial support from the Spanish MCIN/AEI (projects
PID2019-108532GB-I00, PID2020-114653RB-I00, PID2020-
119748GA-I00, PID2021-127127NB-I00, PID2021-128569NB-I00,
and TED2021-131255B-C44 funded by MCIN/AEI/10.13039/
501100011033, Centro de Excelencia Severo Ochoa SEV-2016-
0686, Unidad de Excelencia Maŕıa de Maeztu CEX2019-000919-
M and AEI/FEDER funds), the Comunidad de Madrid (project
QUIMTRONIC-CM (Y2018/NMT-4783)), the Generalitat
Valenciana (projects PROMETEO/2020/077 and MFA/2022/017),
the Junta de Andalućıa (PROYEXCEL-0328) and ERC-2020-SyG
(Project: 951224) “TOMATTO” are acknowledged. This study
was also supported by MCIN with funding from European
Union NextGenerationEU (PRTR-C17.I1) (MAD2D-CM)-MRR
project. M. P.-E. thanks grant PRE2021-097082 funded by
MCIN/AEI and “ESF Investing in your future”.
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© 2023 The Author(s). Published by the Royal Society of Chemistry


	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c

	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c
	Dimeric tetrabromo-p-quinodimethanes: synthesis and structural/electronic propertiesElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d3sc01615c