15 research outputs found
Functionalized Helical Building Blocks for Nanoelectronics
Molecular building blocks are designed
and created for the <i>cis</i>- and <i>trans</i>-dibrominated perylenediimides.
The syntheses are simple and provide these useful materials on the
gram scale. To demonstrate their synthetic versatility, these building
blocks were used to create new dimeric perylenediimide helixes. Two
of these helical dimers are twistacenes, and one is a helicene. Crucially,
each possesses regiochemically defined functionality that allows the
dimer helix to be elaborated into higher oligomers. It would be very
difficult to prepare these helical PDI building blocks regioselectively
without the methods described
Probing the Conductance of the σ‑System of Bipyridine Using Destructive Interference
Guidelines
to predict trends in the electrical conductance of molecules
have been developed for the π-system of conjugated systems.
Little is known, however, about the conductance of the underlying
σ-systems because the π-system usually dominates the transport.
Here we study a family of bipyridine-based molecules using STM-break
junction experiments and density functional theory transport calculations.
We use different lengths and substitution patterns to probe the role
of both the σ-system and the π-system in controlling conductance.
By exploiting the destructive interference feature found in the π-system
of the meta-coupled six-membered aromatic rings, we show that the
conductance of the σ-system of a meta-coupled molecule can be
probed directly and can even exceed that of its para-coupled analog.
These results add to the understanding of the conductance through
the chemically hidden σ-electrons
A Helicene Nanoribbon with Greatly Amplified Chirality
We report the synthesis
and characterization of a chiral, shape-persistent,
perylene-diimide-based nanoribbon. Specifically, the fusion of three
perylene-diimide monomers with intervening naphthalene subunits resulted
in a helical superstructure with two [6]helicene subcomponents. This
π-helix-of-helicenes exhibits very intense electronic circular
dichroism, including one of the largest Cotton effects ever observed
in the visible range. It also displays more than an order of magnitude
increase in circular dichroism for select wavelengths relative to
its smaller homologue. These impressive chiroptical properties underscore
the potential of this new nanoribbon architecture in the context of
chiral electronic materials
A Helicene Nanoribbon with Greatly Amplified Chirality
We report the synthesis
and characterization of a chiral, shape-persistent,
perylene-diimide-based nanoribbon. Specifically, the fusion of three
perylene-diimide monomers with intervening naphthalene subunits resulted
in a helical superstructure with two [6]helicene subcomponents. This
π-helix-of-helicenes exhibits very intense electronic circular
dichroism, including one of the largest Cotton effects ever observed
in the visible range. It also displays more than an order of magnitude
increase in circular dichroism for select wavelengths relative to
its smaller homologue. These impressive chiroptical properties underscore
the potential of this new nanoribbon architecture in the context of
chiral electronic materials
Influence of Molecular Conformation on Electron Transport in Giant, Conjugated Macrocycles
We describe here the direct connection
between the molecular conformation
of a conjugated macrocycle and its macroscopic charge transport properties.
We incorporate chiral, helical perylene diimide ribbons into the two
separate macrocycles as the <i>n</i>-type, electron transporting
material. As the macrocycles’ films and electronic structures
are analogous, the important finding is that the macrocycles’
molecular structures and their associated dynamics determine device
performance in organic field effect transistors. We show the more
flexible macrocycle has a 4-fold increase in electron mobility in
field effect transistor devices. Using a combination of spectroscopy
and density functional theory calculations, we find that the origin
of the difference in device performance is the ability of more flexible
isomer to make intermolecular contacts relative to the more rigid
counterpart
Influence of Molecular Conformation on Electron Transport in Giant, Conjugated Macrocycles
We describe here the direct connection
between the molecular conformation
of a conjugated macrocycle and its macroscopic charge transport properties.
We incorporate chiral, helical perylene diimide ribbons into the two
separate macrocycles as the <i>n</i>-type, electron transporting
material. As the macrocycles’ films and electronic structures
are analogous, the important finding is that the macrocycles’
molecular structures and their associated dynamics determine device
performance in organic field effect transistors. We show the more
flexible macrocycle has a 4-fold increase in electron mobility in
field effect transistor devices. Using a combination of spectroscopy
and density functional theory calculations, we find that the origin
of the difference in device performance is the ability of more flexible
isomer to make intermolecular contacts relative to the more rigid
counterpart
Rigid, Conjugated Macrocycles for High Performance Organic Photodetectors
Organic photodetectors
(OPDs) are attractive for their high optical
absorption coefficient, broad wavelength tunability, and compatibility
with lightweight and flexible devices. Here we describe a new molecular
design that enables high performance organic photodetectors. We use
a rigid, conjugated macrocycle as the electron acceptor in devices
to obtain high photocurrent and low dark current. We make a direct
comparison between the devices made with the macrocyclic acceptor
and an acyclic control molecule; we find that the superior performance
of the macrocycle originates from its rigid, conjugated, and cyclic
structure. The macrocycle’s rigid structure reduces the number
of charged defects originating from deformed <i>sp<sup>2</sup></i> carbons and covalent defects from photo/thermoactivation.
With this molecular design, we are able to suppress dark current density
while retaining high responsivity in an ultrasensitive nonfullerene
OPD. Importantly, we achieve a detectivity of ∼10<sup>14</sup> Jones at near zero bias voltage. This is without the need for extra
carrier blocking layers commonly employed in fullerene-based devices.
Our devices are comparable to the best fullerene-based photodetectors,
and the sensitivity at low working voltages (<0.1 V) is a record
for nonfullerene OPDs
Three-Dimensional Graphene Nanostructures
This Communication
details the implementation of a new concept
for the design of high-performance optoelectronic materials: three-dimensional
(3D) graphene nanostructures. This general strategy is showcased through
the synthesis of a three-bladed propeller nanostructure resulting
from the coupling and fusion of a central triptycene hub and helical
graphene nanoribbons. Importantly, these 3D graphene nanostructures
show remarkable new properties that are distinct from the substituent
parts. For example, the larger nanostructures show an enhancement
in absorption and decreased contact resistance in optoelectronic devices.
To show these enhanced properties in a device setting, the nanostructures
were utilized as the electron-extracting layers in perovskite solar
cells. The largest of these nanostructures achieved a PCE of 18.0%,
which is one of the highest values reported for non-fullerene electron-extracting
layers