This work exposes the importance of testing a polymers active layer thickness tolerance as small modifications to a polymers structure can radically change its ability to stack/pack in the BHJ which is reflected in thick active layer OSCs.
Side-chain
sequence enabled regioisomeric acceptors, bearing different
side-chain sequences on the same conjugated backbone, are herein reported.
Two regioregular polymers PTBI-1 and PTBI-2 and one regiorandom polymer
PTBI-3 were synthesized from these two regioisomeric acceptors for
a comparative study. UV–vis–NIR absorption spectroscopy
and electrochemical study confirmed similar frontier molecular orbital
levels of the three polymers in their solid state. More intriguingly,
absorption profiles suggest that the sequence of side chains greatly
governs the aggregation behaviors. Furthermore, the PTBI-2 film shows
larger ordered domains than PTBI-1 and PTBI-3 films, as supported
by AFM and GIWAXS measurements. As a result, PTBI-2-based FET devices
achieved an average hole mobility of 1.37 cm2 V–1 s–1, much higher than the two polymers with other
side-chain sequences. The regiorandom PTBI-3 exhibited the lowest
average hole mobility of 0.27 cm2 V–1 s–1. This study highlights the significant impact
of side-chain sequence regioisomerism on aggregation behaviors, morphologies,
and subsequently charge transport properties of donor–acceptor
type conjugated polymers.
The existence of point defects, holes, and corrugations
(macroscopic
defects) induces high catalytic potential in graphene and its derivatives.
We report a systematic approach for microscopic and macroscopic defect
density optimization in excimer laser-induced reduced graphene oxide
by varying the laser energy density and pulse number to achieve a
record detection limit of 7.15 nM for peroxide sensing. A quantitative
estimation of point defect densities was obtained using Raman spectroscopy
and confirmed with electrochemical sensing measurements. Laser annealing
(LA) at 0.6 J cm–2 led to the formation of highly
reduced graphene oxide (GO) by liquid-phase regrowth of molten carbon
with the presence of dangling bonds, making it catalytically active.
Hall-effect measurements yielded a mobility of ∼200 cm2 V–1 s–1. An additional
increase in the number of pulses at 0.6 J cm–2 resulted
in deoxygenation through the solid-state route, leading to the formation
of holey graphene structure. The average hole size showed a hierarchical
increase, with the number of pulses characterized with multiple microscopy
techniques, including scanning electron microscopy, atomic force microscopy,
and transmission electron microscopy. The exposure of edge sites due
to high hole density after 10 pulses supported the formation of proximal
diffusion layers, which led to facile mass transfer and improvement
in the detection limit from 25.4 mM to 7.15 nM for peroxide sensing.
However, LA at 1 J cm–2 with 1 pulse resulted in
a high melt lifetime of molten carbon and the formation of GO characterized
by a high resistivity of 3 × 10–2 Ω-cm,
which was not ideal for sensing applications. The rapid thermal annealing
technique using a batch furnace to generate holey graphene results
in structure with uneven hole sizes. However, holey graphene formation
using the LA technique is scalable with better control over hole size
and density. This study will pave the path for cost-efficient and
high-performance holey graphene sensors for advanced sensing applications.
Opioid drugs are extremely potent synthetic analytes, and their abuse is common around the world. Hence, a rapid and point-of-need device is necessary to assess the presence of this compound in body fluid so that a timely countermeasure can be provided to the exposed individuals. Herein, we present an attractive microneedle sensing platform for the detection of the opioid drug fentanyl in real serum samples using an electrochemical detection method. The device contained an array of pyramidal microneedle structures that were integrated with platinum (Pt) and silver (Ag) wires, each with a microcavity opening. The working sensor was modified by graphene ink and subsequently with 4 (3-Butyl-1-imidazolio)-1-butanesulfonate) ionic liquid. The microneedle sensor showed direct oxidation of fentanyl in liquid samples with a detection limit of 27.8 μM by employing a highly sensitive square-wave voltammetry technique. The resulting microneedle-based sensing platform displayed an interference-free fentanyl detection in diluted serum without conceding its sensitivity, stability, and response time. The obtained results revealed that the microneedle sensor holds considerable promise for point-of-need fentanyl detection and opens additional opportunities for detecting substances of abuse in emergencies.
In organic solar cells, maximizing the open-circuit voltage (V OC ) via minimization of the ionization energy or electron affinity offsets of the blended donor and acceptor often comes at the expense of achieving a considerable amount of short-circuit current (J SC ). To explore a hypothesis for the design of materials that may circumvent this tradeoff, eight structurally similar polymers were synthesized consisting of a fluorinated/non-fluorinated benzothiadiazole (BTDF/BTD) strong acceptor moiety, a thiophene ester (TE) weak acceptor, and various donor units composed of bithiophene (T2), biEDOT, and benzodithiophene (BDT) to form six acceptor gradient and two nongradient polymers. The acceptor gradient motif was designed and theorized to induce more facile exciton dissociation in low driving force solar cells by creating a further separated intramolecular charge-transfer state between the strong BTD acceptor and various donor units through a bridging TE component. Solar cells were fabricated using the eight polymers blended with phenyl-C 71 -butyric-acid methyl ester (PC 71 BM) to reveal two top performing isomeric polymers, T2-BTDF-(TE2) and TE2-BTDF-(T2), which were further tested with several non-fullerene acceptors (NFAs): EH-IDTBR, ITIC, and ITIC-4F. In order to fabricate optimally performing solar cells, a 0.2 eV ionization energy offset was found to be essential or the short-circuit current of the NFA cells diminished dramatically. Ultimately, optimized NFA solar cells were fabricated using ITIC-4F paired with each of the top performing polymers to produce an average PCE of 7.3% for TE2-BTDF-(T2) (nongradient) and 3.6% for T2-BTDF-(TE2) (gradient). The acceptor gradient effect was not shown to reduce the amount of charge recombination in NFA solar cells mainly due to the inability to fabricate solar cells, with minimal ionization energy or electron affinity offsets along with morphological complications. This work stresses the importance of acquiring accurate ionization energies and electron affinities when characterizing solar cell energetics, as differences as small as 0.1 eV in the offsets can make a significant impact on overall charge collection.
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