A 1,1,4,4-tetracyanobuta-1,3-diene (TCBD)-aniline moiety has been introduced, for the first time, at the axial position of two subphthalocyanines (SubPcs) peripherally substituted with hydrogen (HSubPc) or fluorine atoms (FSubPc). Single-crystal X-ray analysis of both SubPc-TCBD-aniline systems showed that each conjugate is a racemic mixture of two atropisomers resulting from the almost orthogonal geometry adopted by the axial TCBD unit, which were separated by chiral high-performance liquid chromatography. Remarkably, the single-crystal X-ray structure of one atropisomer of each SubPc-TCBD-aniline conjugate has been solved, allowing to unambiguously assign the atropisomers' absolute configuration, something, to the best of our knowledge, unprecedented in TCBD-based conjugates. Moreover, the physicochemical properties of both SubPc-TCBD-aniline racemates have been investigated using a wide range of electrochemical as well as steady-state and time-resolved spectroscopic techniques. Each of the two SubPc-TCBD-aniline conjugates presents a unique photophysical feature never observed before in SubPc chemistry. As a matter of fact, HSubPc-TCBD-aniline showed significant ground-state charge transfer interactions between the HSubPc macrocycle and the electron-withdrawing TCBD unit directly attached at its axial position. In contrast, FSubPc-TCBD-aniline gave rise to an intense, broad emission, which red shifts upon increasing the solvent polarity and stems from an excited complex (i.e., an exciplex). Such an exciplex emission, which has also no precedent in TCBD chemistry, results from intramolecular interactions in the excited state between the electron-rich aniline and the FSubPc π-surface, two molecular fragments kept in spatial proximity by the "unique" three-dimensional geometry adopted by the FSubPc-TCBD-aniline. Complementary transient absorption studies were carried out on both SubPc-TCBD-aniline derivatives, showing the occurrence, in both cases, of photoinduced charge separation and corroborating the formation of the aforementioned intramolecular exciplex in terms of a radical ion pair stabilized through-space.
We present an in-depth investigation regarding the electron-accepting nature of pressure-synthesized carbon nanodots (pCNDs) in combination with porphyrins as excited-state electron donors. To this end, electrostatic attractions involving negative charges, which are present on the pCND surface, are essential to govern the hybrid assembly, on one hand, and charge separation, on the other hand.
We report the stereoisomerism and physicochemical properties of two novel electron donor–acceptor conjugates based on subphthalocyanines decorated at their peripheral, or peripheral/axial positions with multiple tetracyanobutadiene–aniline moieties.
We
report here the synthesis of two novel subporphyrins (SubPs),
in which the macrocycle has been functionalized at its meso (1) or axial (2) position with tetracyanobuta-1,3-diene
(TCBD)–aniline. In-depth spectroscopic, spectrometric, and
electrochemical analyses were carried out with both of them, whose
molecular structures were determined by single-crystal X-ray diffraction
studies. In the case of 2, its R
a and S
a enantiomers were separable
by chiral HPLC and presented a fairly good configurational stability
at room temperature, which enabled determining the activation parameters
for the thermally induced racemization. Conversely, the enantiomers’
separation was unfeasible for 1 due to the conformational
and/or configurational dynamics of the TCBD–aniline, a structural
“flexibility” that could be drastically reduced at low
temperatures. The physicochemical impact of placing the TCBD–aniline
at either the axial or peripheral positions of SubPs is also rather
significant. The HOMO–LUMO gap is reduced by as much as 0.35
eV in SubP–(TCBD–aniline)
meso
1 (1.77 eV) and, in turn, enables an emissive charge-transfer
(CT) state in virtually all environments. It is only in polar environments,
where it links a local excitation with an indirect charge separation.
In contrast, a much larger HOMO–LUMO gap of 2.12 eV in SubP–(TCBD–aniline)axial
2 disables an emissive CT state and enforces
either an exciplex deactivation in apolar environments or a direct
charge separation in polar environments.
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