5 research outputs found
Selective Syntheses of [7]–[12]Cycloparaphenylenes Using Orthogonal Suzuki–Miyaura Cross-Coupling Reactions
The divergent, selective syntheses of [7]–[12]cycloparaphenylenes
have been accomplished utilizing sequential, orthogonal Suzuki–Miyaura
cross-coupling reactions from two late-stage intermediates. Quantum
yields decrease dramatically as cycloparaphenylene size decreases,
highlighting the unique photophysical behavior of the smaller cycloparaphenylenes
Molecular Materials for Nonaqueous Flow Batteries with a High Coulombic Efficiency and Stable Cycling
This
manuscript presents a working redox battery in organic media
that possesses remarkable cycling stability. The redox molecules have
a solubility over 1 mol electrons/liter, and a cell with 0.4 M electron
concentration is demonstrated with steady performance >450 cycles
(>74 days). Such a concentration is among the highest values reported
in redox flow batteries with organic electrolytes. The average Coulombic
efficiency of this cell during cycling is 99.868%. The stability of
the cell approaches the level necessary for a long lifetime nonaqueous
redox flow battery. For the membrane, we employ a low cost size exclusion
cellulose membrane. With this membrane, we couple the preparation
of nanoscale macromolecular electrolytes to successfully avoid active
material crossover. We show that this cellulose-based membrane can
support high voltages in excess of 3 V and extreme temperatures (−20
to 110 °C). These extremes in temperature and voltage are not
possible with aqueous systems. Most importantly, the nanoscale macromolecular
platforms we present here for our electrolytes can be readily tuned
through derivatization to realize the promise of organic redox flow
batteries
Long-Lived Charge Separation at Heterojunctions between Semiconducting Single-Walled Carbon Nanotubes and Perylene Diimide Electron Acceptors
Nonfullerene electron
acceptors have facilitated a recent surge
in the efficiencies of organic solar cells, although fundamental studies
of the nature of exciton dissociation at interfaces with nonfullerene
electron acceptors are still relatively sparse. Semiconducting single-walled
carbon nanotubes (s-SWCNTs), unique one-dimensional electron donors
with molecule-like absorption and highly mobile charges, provide a
model system for studying interfacial exciton dissociation. Here,
we investigate excited-state photodynamics at the heterojunction between
(6,5) s-SWCNTs and two perylene diimide (PDI)-based electron acceptors.
Each of the PDI-based acceptors, <b>hPDI2-pyr-hPDI2</b> and <b>Trip-hPDI2</b>, is deposited onto (6,5) s-SWCNT films to form
a heterojunction bilayer. Transient absorption measurements demonstrate
that photoinduced hole/electron transfer occurs at the photoexcited
bilayer interfaces, producing long-lived separated charges with lifetimes
exceeding 1.0 μs. Both exciton dissociation and charge recombination
occur more slowly for the <b>hPDI2-pyr-hPDI2</b> bilayer than
for the <b>Trip-hPDI2</b> bilayer. To explain such differences,
we discuss the potential roles of the thermodynamic charge transfer
driving force available at each interface and the different molecular
structure and intermolecular interactions of PDI-based acceptors.
Detailed photophysical analysis of these model systems can develop
the fundamental understanding of exciton dissociation between organic
electron donors and nonfullerene acceptors, which has not been systematically
studied
Helical Nanoribbons for Ultra-Narrowband Photodetectors
This Communication
describes a new molecular design that yields
ultranarrowband organic photodetectors. The design is based on a series
of helically twisted molecular ribbons as the optoelectronic material.
We fabricate charge collection narrowing photodetectors based on four
different helical ribbons that differ in the wavelength of their response.
The photodetectors made from these materials have narrow spectral
response with full-width at half maxima of <20 nm. The devices
reported here are superior by approximately a factor of 5 to those
from traditional organic materials due to the narrowness of their
response. Moreover, the active layers for the helical ribbon-based
photodetectors are solution-cast but have performance that is comparable
to the state-of-the-art narrowband photodetectors made from methylammonium
lead trihalide perovskite single crystals. The ultranarrow bandwidth
for detection results from the helical ribbons’ high absorption
coefficient, good electron mobility, and sharp absorption edges that
are defined by the twisted molecular conformation
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