12 research outputs found
Tailoring Atropisomeric Maleimides for Stereospecific [2 + 2] PhotocycloadditionPhotochemical and Photophysical Investigations Leading to Visible-Light Photocatalysis
Atropisomeric maleimides
were synthesized and employed for stereospecific
[2 + 2] photocycloaddition. Efficient reaction was observed under
direct irradiation, triplet-sensitized UV irradiation, and non-metal
catalyzed visible-light irradiation, leading to two regioisomeric
(<i>exo</i>/<i>endo</i>) photoproducts with complete
chemoselectivity (exclusive [2 + 2] photoproduct). High enantioselectivity
(ee > 98%) and diastereoselectivity (dr > 99:1%) were observed
under
the employed reaction conditions and were largely dependent on the
substituent on the maleimide double bond but minimally affected by
the substituents on the alkenyl tether. On the basis of detailed photophysical
studies, the triplet energies of the maleimides were estimated. The
triplet lifetimes appeared to be relatively short at room temperature
as a result of fast [2 + 2] photocycloaddition. For the visible-light
mediated reaction, triplet energy transfer occurred with a rate constant
close to the diffusion-limited value. The mechanism was established
by generation of singlet oxygen from the excited maleimides. The high
selectivity in the photoproduct upon reaction from the triplet excited
state was rationalized on the basis of conformational factors as well
as the type of diradical intermediate that was preferred during the
photoreaction
Tailoring Atropisomeric Maleimides for Stereospecific [2 + 2] PhotocycloadditionPhotochemical and Photophysical Investigations Leading to Visible-Light Photocatalysis
Atropisomeric maleimides
were synthesized and employed for stereospecific
[2 + 2] photocycloaddition. Efficient reaction was observed under
direct irradiation, triplet-sensitized UV irradiation, and non-metal
catalyzed visible-light irradiation, leading to two regioisomeric
(<i>exo</i>/<i>endo</i>) photoproducts with complete
chemoselectivity (exclusive [2 + 2] photoproduct). High enantioselectivity
(ee > 98%) and diastereoselectivity (dr > 99:1%) were observed
under
the employed reaction conditions and were largely dependent on the
substituent on the maleimide double bond but minimally affected by
the substituents on the alkenyl tether. On the basis of detailed photophysical
studies, the triplet energies of the maleimides were estimated. The
triplet lifetimes appeared to be relatively short at room temperature
as a result of fast [2 + 2] photocycloaddition. For the visible-light
mediated reaction, triplet energy transfer occurred with a rate constant
close to the diffusion-limited value. The mechanism was established
by generation of singlet oxygen from the excited maleimides. The high
selectivity in the photoproduct upon reaction from the triplet excited
state was rationalized on the basis of conformational factors as well
as the type of diradical intermediate that was preferred during the
photoreaction
Light-Induced Enantiospecific 4π Ring Closure of Axially Chiral 2-Pyridones: Enthalpic and Entropic Effects Promoted by H-Bonding
Nonbiaryl axially chiral 2-pyridones were synthesized and employed for light-induced electrocyclic 4π ring closure leading to bicyclo-β-lactam photoproducts in solution. The enantioselectivity in the photoproducts varied from 22 to 95% depending on the reaction temperature and the ability of the axially chiral chromophore to form intramolecular and/or intermolecular H-bonds with the solvent. On the basis of the differential activation parameters, entropic control of the enantiospecificity was observed for 2-pyridones lacking the ability to form H-bonds. Conversely, enthalpy played a significant role for 2-pyridones having the ability to form H-bonds
Light-Induced Enantiospecific 4π Ring Closure of Axially Chiral 2-Pyridones: Enthalpic and Entropic Effects Promoted by H-Bonding
Nonbiaryl axially chiral 2-pyridones were synthesized and employed for light-induced electrocyclic 4π ring closure leading to bicyclo-β-lactam photoproducts in solution. The enantioselectivity in the photoproducts varied from 22 to 95% depending on the reaction temperature and the ability of the axially chiral chromophore to form intramolecular and/or intermolecular H-bonds with the solvent. On the basis of the differential activation parameters, entropic control of the enantiospecificity was observed for 2-pyridones lacking the ability to form H-bonds. Conversely, enthalpy played a significant role for 2-pyridones having the ability to form H-bonds
Probing Through-Bond and Through-Space Interactions in Singlet Fission-Based Pentacene Dimers
Interchromophoric
interactions such as Coulombic coupling and exchange
interactions are crucial to the functional properties of numerous
π-conjugated systems. Here, we use magnetic circular dichroism
(MCD) spectroscopy to investigate interchromophoric interactions in
singlet fission relevant pentacene dimers. Using a simple analytical
model, we outline a general relationship between the geometry of pentacene
dimers and their calculated MCD response. We analyze experimental
MCD spectra of different covalently bridged pentacene dimers to reveal
how the molecular structure of the “bridge” affects
the magnitude of through-space Coulombic and through-bond exchange
interactions in the system. Our results show that through-bond interactions
are significant in dimers with conjugated molecules as bridging units
and these interactions promote the overall electronic coupling in
the system. Our generalized approach paves the way for the application
of MCD in investigating interchromophoric interactions across a range
of π-conjugated systems
Transposed Paternò–Büchi Reaction
A complementary
strategy of utilizing ππ* excited state
of alkene instead of nπ* excited state of the carbonyl chromophore
in a “transposed Paternò–Büchi”
reaction is evaluated with atropisomeric enamides as the model system.
Based on photophysical investigations, the nature of excited states
and the reactive pathway was deciphered leading to atropselective
reaction. This new concept of switching of excited-state configuration
should pave the way to control the stereochemical course of photoreaction
due to the orbital approaches required for photochemical reactivity
Exciton Correlations in Intramolecular Singlet Fission
We have synthesized
a series of asymmetric pentacene–tetracene
heterodimers with a variable-length conjugated bridge that undergo
fast and efficient intramolecular singlet fission (iSF). These compounds
have distinct singlet and triplet energies, which allow us to study
the spatial dynamics of excitons during the iSF process, including
the significant role of exciton correlations in promoting triplet
pair generation and recombination. We demonstrate that the primary
photoexcitations in conjugated dimers are delocalized singlets that
enable fast and efficient iSF. However, in these asymmetric dimers,
the singlet becomes more localized on the lower energy unit as the
length of the bridge is increased, slowing down iSF relative to analogous
symmetric dimers. We resolve the recombination kinetics of the inequivalent
triplets produced via iSF, and find that they primarily decay via
concerted processes. By identifying different decay channels, including
delayed fluorescence via triplet–triplet annihilation, we can
separate transient species corresponding to both correlated triplet
pairs and uncorrelated triplets. Recombination of the triplet pair
proceeds rapidly despite our experimental and theoretical demonstration
that individual triplets are highly localized and unable to be transported
across the conjugated linker. In this class of compounds, the rate
of formation and yield of uncorrelated triplets increases with bridge
length. Overall, these constrained, asymmetric systems provide a unique
platform to isolate and study transient species essential for singlet
fission, which are otherwise difficult to observe in symmetric dimers
or condensed phases
Properties of Poly- and Oligopentacenes Synthesized from Modular Building Blocks
We describe a facile route to well-defined,
solution-processable
pentacene oligomers (2 to 7) and homopolymer using Suzuki–Miyaura
cross-coupling reactions. Because this synthetic strategy leads to
regioisomers, regiopure <i>syn</i>- and <i>anti</i>-trimers were also synthesized, revealing minimal changes in solution
properties but significant changes in the solid state arising from
differing levels of crystallinity. The materials were characterized
by steady state absorption spectroscopy and cyclic voltammetry to
study their electronic structure. The steady state absorption spectra
exhibit a new high-energy transition in the oligomers, which intensifies
as a function of oligomer length, thus increasing the range of absorption
to include the entire visible spectrum. Density functional theory
calculations indicate that the new peak results directly from the
oligomerization. Solid state UV–vis suggests that while the
monomer is amorphous, bricklayer packing in the higher oligomers significantly
alters the solid state absorption relative to solution. This effect
of oligomerization on packing was corroborated by GIWAXS analysis,
which revealed crystalline domains in the oligomers. These domains,
which are most evident in <i>anti</i>-trimer, become more
pronounced upon thermal annealing. Photodegradation studies revealed
considerable stability enhancement of oligomers toward oxygen and
cycloaddition reactions relative to monomer. The synthesis and characterization
of the first higher oligomers and homopolymer of pentacene should
pave the way to applications in singlet fission, organic field-effect
transistors, and organic photovoltaics
A Direct Mechanism of Ultrafast Intramolecular Singlet Fission in Pentacene Dimers
Interest in materials
that undergo singlet fission (SF) has been
catalyzed by the potential to exceed the Shockley–Queisser
limit of solar power conversion efficiency. In conventional materials,
the mechanism of SF is an intermolecular process (xSF), which is mediated
by charge transfer (CT) states and depends sensitively on crystal
packing or molecular collisions. In contrast, recently reported covalently
coupled pentacenes yield ∼2 triplets per photon absorbed in
individual molecules: the hallmark of intramolecular singlet fission
(iSF). However, the mechanism of iSF is unclear. Here, using multireference
electronic structure calculations and transient absorption spectroscopy,
we establish that iSF can occur via a direct coupling mechanism that
is independent of CT states. We show that a near-degeneracy in electronic
state energies induced by vibronic coupling to intramolecular modes
of the covalent dimer allows for strong mixing between the correlated
triplet pair state and the local excitonic state, despite weak direct
coupling
Quantitative Intramolecular Singlet Fission in Bipentacenes
Singlet
fission (SF) has the potential to significantly enhance
the photocurrent in single-junction solar cells and thus raise the
power conversion efficiency from the Shockley–Queisser limit
of 33% to 44%. Until now, quantitative SF yield at room temperature
has been observed only in crystalline solids or aggregates of oligoacenes.
Here, we employ transient absorption spectroscopy, ultrafast photoluminescence
spectroscopy, and triplet photosensitization to demonstrate intramolecular
singlet fission (iSF) with triplet yields approaching 200% per absorbed
photon in a series of bipentacenes. Crucially, in dilute solution
of these systems, SF does not depend on intermolecular interactions.
Instead, SF is an intrinsic property of the molecules, with both the
fission rate and resulting triplet lifetime determined by the degree
of electronic coupling between covalently linked pentacene molecules.
We found that the triplet pair lifetime can be as short as 0.5 ns
but can be extended up to 270 ns