Gum‐Like Nanocomposites as Conformable,Conductive, and Adhesive Electrode Matrix for Energy Storage Devices

The electrodes in energy storage devices, such as lithium/sodium ion batteries, are typical multicomponent system consisting of inorganic electrode particles, polymer binders, conductive fillers, current collectors, and other components. These components are usually porously combined by a polymeric binder to accomplish the required electrochemical functions. In spite of the great success, this classic porous configuration faces serious issues in mechanical stability and flexibility due to weak and instable structures/interfaces. Here, by learning from polymeric nanocomposites, a concept of electrode matrix is proposed based on a gum‐like nanocomposite, a dual‐conductive adhesive. As an electrode matrix, the gum‐like nanocomposite integrates the functions of binder, electrolyte, and conductive fillers. In particular, it shows strong adhesion, high electrical/ionic conductivities, and appropriate mechanical and self‐healing properties. Finally, it is demonstrated that, with the electrode matrix, battery electrodes can be fabricated into nonporous composite showing not only excellent mechanical flexibility/stability but also improved electrochemical performance when working with a gum‐like electrolyte.     

All‐Manganese‐Based Binder‐Free Stretchable Lithium‐Ion Batteries

Advanced electrode materials with bendability and stretchability are critical for the rapid development of fully flexible/stretchable lithium‐ion batteries. However, the sufficiently stretchable lithium‐ion battery is still underdeveloped that is one of the biggest challenges preventing from realizing fully deformable power sources. Here, a low‐temperature hydrothermal synthesis of a cathode material for stretchable lithium‐ion battery is reported by the in situ growth of LiMn₂O₄ (LMO) nanocrystals inside 3D carbon nanotube (CNT) film networks. The LMO/CNT film composite has demonstrated the chemical bonding between the LMO active materials and CNT scaffolds, which is the most important characteristic of the stretchable electrodes. When coupled with a wrinkled MnO_x /CNT film anode, a binder‐free, all‐manganese‐based stretchable full battery cell is assembled which delivers a high average specific capacity of ≈97 mA h g^?1 and stabilizes after over 300 cycles with an enormous strain of 100%. Furthermore, combining with other merits such as low cost, natural abundance, and environmentally friendly, the all‐manganese design is expected to accelerate the practical applications of stretchable lithium‐ion batteries for fully flexible and biomedical electronics.     

集成微管路电位分析及其在生态学研究中的应用

本文介绍了集成微管路电位分析原理,实验装置、分析特点及其在生态学研究中的应用。采用此微型装置测定了土壤、植物、水、血清、药物中的K~ 、Na~ 、Cl~-、pH、NH_3、NO_3~-、Ca~(2 )、Mg~(2 )、F~-、CN~-、I~-、S~-/Ag~ 、阿托品、东茛菪碱等,并和各种标准分析方法进行了比较,结果一致。鉴于集成微管路引入分析领域所提供的优点,它将在生态学研究中发挥重要作用。     

ITO‐Free,Small‐Molecule Organic Solar Cells on Spray‐Coated Copper‐Nanowire‐Based Transparent Electrodes

The great potential of solution‐processed metal nanowire networks utilized as a transparent electrode has attracted much attention in the last years. Typically, silver nanowires are applied, although their replacement by more abundant and cheaper materials is of interest. Here, a hydrazine‐free synthesis route for high aspect ratio copper nanowires is used to prepare conductive networks showing an enhanced electrode performance. The network deposition is done with a scalable spray‐coating process on glass and on polymer foils. By a pressing or an annealing step, highly conductive transparent electrodes are obtained, and they reveal transmittance‐resistance values similar to indium tin oxide (ITO) and networks made of silver nanowires. The application potential of the copper nanowire electrodes is demonstrated by integrating them into an evaporated small‐molecule organic solar cell with 3% efficiency.     

Observation of Electrochemically Driven Elemental Segregation in a Si Alloy Thin‐Film Anode and its Effects on Cyclic Stability for Li‐Ion Batteries

The results of employing (Ti, Fe)‐alloyed Si thin‐film anode for Li‐ion batteries are reported. The material demonstrates an impressive cyclic stability with stable operation for more than 500 cycles at a capacity higher than 1400 mAh g^?1. Materials characterization using scanning electron microscopy and transmission electron microscopy illuminates an intriguing materials process behind the performance: ripple‐like pattern formation via electrochemically driven segregation of the inactive elements (Ti and Fe). The ripple structure plays a buffer role by suppressing loss of the active material upon further cycling, allowing the anode to gradually transform into an array of microbumps. The morphological evolution helps the anode endure long cycles (even up to 1000 cycles) without catastrophic failure as the bumps shrank slowly and steadily, consistent with the electrochemical data.     

Poly(U)-Agarose Affinity Chromatography: Specific,Sensitivity Selectivity,and Affinity of Binding

These studie s were done to determine four basic intrinsic properties of poly(U)-agarose affinity columns. Specificity of binding studies demonstrated that binding to these columns is highly specific with >90% complementary binding and 3% noncomplementary binding. Sensitivity of binding studies indicated that a minimum sequence of 10 adenylates is required for detectable complementary binding. Selectivity of binding studies revealed that nonsequential adenylates in native RNAs and randomly distribut edadenylates in synthetic poly(A)-poly(C) co-polymers did not bind to poly(U)-agarose affinity columns. Whereas, affinity of binding studies demonstrated that A=U complementary base pairing is independent of chain-lengths of 25 a denylates and dependent of chain-lengths of <25 adenylates. Thus the data demonstrates that poly(U)-agarose affinity chromatography is scientifically sound and expedient for thedetection and isolation of poly(A)-containing cellular and viral RNAs.