Three-in-One Strategy Enables Single-Component Organic Solar Cells with Record Efficiency and High Stability.

Single-component organic solar cells (SCOSCs) with covalently bonding donor and acceptor are becoming increasingly attractive because of their superior stability over traditional multicomponent blend organic solar cells (OSCs). Nevertheless, the efficiency of SCOSCs is far behind the state-of-the-art multicomponent OSCs. Herein, by combination of the advantages of three-component and single-component devices, this work reports an innovative three-in-one strategy to boost the performance of SCOSCs. In this three-in-one strategy, three independent components (PM6, D18, and PYIT) are covalently linked together to create a new single-component active layer based on ternary conjugated block copolymer (TCBC) PM6-D18-b-PYIT by a facile polymerization. Precisely manipulating the component ratios in the polymer chains of PM6-D18-b-PYIT is able to broaden light utilization, promote charge dynamics, optimize, and stabilize film morphology, contributing to the simultaneously enhanced efficiency and stability of the SCOSCs. Ultimately, the PM6-D18-b-PYIT-based device exhibits a power conversion efficiency (PCE) of 14.89%, which is the highest efficiency of the reported SCOSCs. Thanks to the aggregation restriction of each component and chain entanglement in the three-in-one system, the PM6-D18-b-PYIT-based SCOSC displays significantly higher stability than the corresponding two-component (PM6-D18:PYIT) and three-component (PM6:D18:PYIT). These results demonstrate that the three-in-one strategy is facile and promising for developing SCOSCs with superior efficiency and stability.

Regulating the Sequence Structure of Conjugated Block Copolymers Enables Large-Area Single-Component Organic Solar Cells with High Efficiency and Stability.

Single-component organic solar cells (SCOSCs) based on conjugated block copolymers (CBCs) by covalently bonding a polymer donor and polymer acceptor become more and more appealing due to the formation of a favorable and stable morphology. Unfortunately, a deep understanding of the effect of the assembly behavior caused by the sequence structure of CBCs on the device performance is still missing. Herein, from the aspect of manipulating the sequence length and distribution regularity of CBCs, we synthesized a series of new CBCs, namely D18(20)-b-PYIT, D18(40)-b-PYIT and D18(60)-b-PYIT by two-pot polymerization, and D18(40)-b-PYIT(r) by traditional one-pot method. It is observed that precise manipulation of sequence length and distribution regularity of the polymer blocks fine-tunes the self-assembly of the CBCs, optimizes film morphology, improves optoelectronic properties, and reduces energy loss, leading to simultaneously improved efficiency and stability. Among these CBCs, the D18(40)-b-PYIT-based device achieves a high efficiency of 13.4 % with enhanced stability, which is an outstanding performance among SCOSCs. Importantly, the regular sequence distribution and suitable sequence length of the CBCs enable a facile film-forming process of the printed device. For the first time, the blade-coated large-area rigid/flexible SCOSCs are fabricated, delivering an impressive efficiency of 11.62 %/10.73 %, much higher than their corresponding binary devices.

Oligomer-Assisted Photoactive Layers Enable >18 % Efficiency of Organic Solar Cells.

Although ternary organic solar cells (OSCs) have unique advantages in improving device performance, the morphology assembly in the ternary-phase would be more uncertain or complex than that in the binary-phase. Here, we propose a new concept of oligomer-assisted photoactive layers for high-performance OSCs. The formed alloy-like phase of the oligomer : host polymer blend enabled the oligomer-assisted OSCs to fuse the advantages of both binary and ternary devices, exhibiting substantially enhanced performance and stability compared to the control devices. With the addition of oligomers, outstanding efficiencies of 17.33 % for a PM6 : Y6 device, 18.32 % for a PM6 : BTP-eC9 device, and 17.13 % for a PM6/Y6 pseudo-bilayer device were achieved, all of which are one of the highest values in their corresponding fields. The improved performance originated from the downshift energy levels, enhanced light absorption, optimized blend morphology, favorable charge dynamics, and reduced non-radiative energy loss.

Alkylsilyl Fused Ring-Based Polymer Donor for Non-Fullerene Solar Cells with Record Open Circuit Voltage and Energy Loss.

The energy loss (Eloss ), especially the nonradiative recombination loss and energetic disorder, needs to be minimized to improve the device performance with a small voltage (VOC ) loss. Urbach energy (EU ) of organic photovoltaic materials is related to energetic disorder, which can predict the Eloss of the corresponding device. Herein, a polymer donor (PBDS-TCl) with Si and Cl functional atoms for organic solar cells (OSCs) is synthesized. It can be found that the VOC and Eloss can be well manipulated by regulation of the energy level of the polymer donor and EU , which is dominated by the morphology. A low energetic disorder with an EU of 23.7 meV, a low driving force of 0.08 eV, and a low Eloss of 0.41 eV are achieved for the PBDS-TCl:Y6-based OSCs. Consequently, an impressive open circuit voltage (VOC ) of 0.92 V is obtained. To the best of knowledge, the VOC value and Eloss are both the record values for the Y6-based device. These results demonstrate that fine-tuning the polymer donor by functional atom modification on the side chain is a promising way to reduce EU and energy loss, as well as obtain small driving force and high VOC for highly efficient OSCs.

A novel AIE molecule as a hole transport layer enables efficient and stable perovskite solar cells.

A low-cost and efficient hole transport layer (HTL) material (TPE-CZ) with the aggregation-induced emission (AIE) effect has been synthesized. Due to the AIE effect, perovskite solar cells with TPE-CZ as the HTL deliver a higher power conversion efficiency (PCE) of 18% with better stability than those with the reference HTL (Spiro-OMeTAD).

Rapid determination of aflatoxins in corn and peanuts.

A rapid and simple method using ultra-high-pressure liquid chromatography with UV detection for the determination of aflatoxins B1, B2, G1 and G2 in corn and peanuts has been developed. In this method, aflatoxins were extracted with a mixture of acetonitrile and water (86:14) and then purified by solid-phase clean-up with a MycoSep#226 AflaZon(+) column. The toxins were determined by UPLC-UV without derivatizing aflatoxins in real samples, which has not been used in other studies. The mean recoveries of aflatoxins from non-infected peanut and corn samples spiked with aflatoxins B1, B2, G1 and G2 at concentrations from 0.22 to 5 microg/kg were between 83.4% and 94.7%. The detection limits (S/N=3) for B1, B2, G1 and G2 were 0.32, 0.19, 0.32 and 0.19 microg/kg, and the corresponding quantification limits (S/N=10) were 1.07, 0.63, 1.07 and 0.63 microg/kg, respectively. We also applied this method on real samples. Among 16 peanut samples, 2 (12.5% incidence) were contaminated with aflatoxin; among 18 corn samples, 4 (22% incidence) were contaminated. The proposed method is rapid, simple and accurate for monitoring aflatoxins in corn and peanuts.

[Determination of pralidoxime chloride in rat plasma by high performance liquid chromatography].

OBJECTIVE: To provide a reference for clinically curing organophosphrous compounds Poisoning. A high performance liquid chromatography method has been developed for determination of pralidoxime chloride in rat plasma. BECKMAN ODS C18 column, Waters Model 510 HPLC pump and 996 photodiode Detector were used. The mobile phase consisted of 7.5% acetonitrile and 92.5% (20nmol/L NaH2PO4, 0.2% C8H17SO3 Na, pH3.0, adjusted by H3PO4 Solution) the flow rate was 1.0mol/min. detection wavelength was set at 296. The samples were pretreated with acetonitrite. The results show a good liner correlation between pralidoxime chloride concentration(from 1.0 - 5.0 microg/ml) and absorption intensity. The detection limit is 0.5 microg/ml with signal to noise ratio of 2. The intra-assay and inter-assay coefficients of variation were 1.35% and 2.73%. The recoveries for plasma were in ranges of 76% - 84%.