Synthesis and characterization of low temperature Sn nanoparticles for the fabrication of highly conductive ink

To fabricate a low cost, highly conductive ink for inkjet printing, we synthesized a gram scale of uniformly sized Sn nanoparticles by using a modified polyol process and observed a significant size-dependent melting temperature depression from 234.1?°C for bulk Sn to 177.3?°C for 11.3 nm Sn nanoparticles. A 20 wt% of Sn nanoparticles was dispersed in the 50% ethylene glycol: 50% isopropyl alcohol mixed solvent for the appropriate viscosity (11.6 cP) and surface tension (32 dyn cm(-1)). To improve the electrical property, we applied the surface treatments of hydrogen reduction and plasma ashing. The two treatments had the effect of diminishing the sheet resistance from 1 kΩ/sq to 50 Ω/sq. In addition, conductive patterns (1 cm × 1 cm) were successfully drawn on the Si wafer using an inkjet printing instrument with conductive Sn ink. The maximum resistivity for an hour of sintering at 250?°C was 64.27 μΩ cm, which is six times higher than the bulk Sn resistivity (10.1 μΩ cm).     

Simultaneous activity assay of two transglutaminase isozymes, blood coagulation factor XIII and transglutaminase 2, by use of fibrinogen arrays

We developed an on-chip activity assay system to simultaneously determine the transamidating activities of blood coagulation factor XIII (FXIII) and transglutaminase 2 (TG2) by use of fibrinogen arrays. FXIII and TG2 are transglutaminase family members that are involved in various physiological functions, including vascular pathophysiology, bone development, and cancer progression. However, investigation of their differential functions is limited by the lack of high-throughput and isozyme-specific activity assays. For the on-chip activity assay, we fabricated protein arrays by immobilizing fibrinogen onto the 3-aminopropyltrimethoxysilane surface of well-type arrays, and we determined transamidating activity by probing biotinylated fibrinogen with Cy3-conjugated streptavidin on arrays. We optimized assay conditions, such as buffer pH, concentrations of dithiothreitol and 5-(biotinamido)pentylamine, and incubation time, and we created equations to determine specific FXIII and TG2 activities in samples. We successfully applied this assay system to monitor changes in FXIII and TG2 activities in THP-1 monocytic cells differentiated with phorbol 12-myristate13-acetate and interleukin-4. This activity assay is sensitive and suitable for high-throughput determination of FXIII and TG2 activities and thus has a strong potential for investigating the differential functions of these isozymes in cell signaling and cardiovascular pathophysiology research.     

Efficient white organic light-emitting diodes with mixed electron transporting layers

The authors demonstrated phosphorescent white organic light-emitting diodes (PHWOLED) with mixed electron transporting layers (M-ETL) using 4,7-diphenyl-1,10-phenanthroline (BPhen)/4,4′-bis (carbazol-9-yl)biphenyl (CBP). The M-ETL PHWOLED exhibited the optimum balance of holes and electrons, owing to the low electron mobility of the CBP M-ETL. The optimized PHWOLED showed a peak current efficiency of 16.85 cd/A and a peak external quantum efficiency of 7.32%.     

Directed self-assembly of organic semiconductors via confined evaporative capillary flows for use in organic field-effect transistors

We fabricated well-defined 6,13-bis(triisopropylsilylethynyl) pentacene (TIPS-PEN) crystal arrays for use in electronic applications via a simple but effective method, the confined evaporative capillary flow (CEC) method. This has been accomplished by systematically controlling the contact line pinning at the edge of glass stylus and the outward hydrodynamic flow within the drying droplet with various processing solvents and surface properties of the substrate during solidification. We found that after CEC coating of TIPS-PEN solution dissolved into toluene onto SiO₂ surface, ribbon-shaped TIPS-PEN crystals were well developed with a width of 20–100 μm and length of 300 μm – 2 mm, which is presumably owing to optimized capillary evaporation. Specifically, TIPS-PEN crystals present highly preferred crystal orientation along the (l 0 0) axis, which can lead to efficient charge transport in a lateral direction. Thus, TIPS-PEN field-effect transistors (FETs) exhibited a good hole mobility of 0.72 cm²/Vs.     

Toward a Nanoscale-Defect-Free Ni-Rich Layered Oxide Cathode Through Regulated Pore Evolution for Long-Lifespan Li Rechargeable Batteries

Ni-rich layered oxides are envisioned as the most promising cathode materials for next-generation lithium-ion batteries; however, their practical adoption is plagued by fast capacity decay originating from chemo-mechanical degradation. The intrinsic chemical–mechanical instability, inherited from atomic- and nanoscale defects generated during synthesis, is not yet resolved. Here, atomic- and nanoscale structural evolution during solid-state synthesis of Ni-rich layered cathode, Li[Ni_0.92Co_0.03Mn_0.05]O₂, is investigated using combined X-ray/neutron scattering and electron/X-ray microscopy. The multiscale analyses demonstrate the intertwined correlation between phase transition and microstructural evolution, with atomic-scale defects derived from the decomposition of precursors leading to the creation of intra/inter-granular pores. The nucleation and coalescence mechanism of pore defects during the synthesis of Ni-rich layered cathodes are quantitatively revealed. Furthermore, a modified synthetic route is proposed to effectively circumvent the formation of nanoscale defects in Ni-rich layered cathodes by facilitating uniform synthetic reactions, resulting in superior electrochemical and microstructural stability.