Hydrogel electrolytes have high room-temperature conductivity and can be widely used in energy storage device. However, hydrogels suffer from the inevitable freezing of water at subzero temperatures, resulting in the diminishment of their conductivity and mechanical properties. How to achieve high conductivity without sacrificing hydrogels' flexibility at subzero temperature is an important challenge. To address this challenge, a new type of zwitterionic polymer hydrogel (polySH) electrolytes is fabricated. The anionic and cationic counterions on the polymer chains facilitate the dissociation of LiCl. The antifreezing electrolyte can be stretched to a strain of 325% and compressed to 75% at −40 °C and possesses an outstanding conductivity of 12.6 mS cm −1 at −40 °C. A direct hopping migration mechanism of hydrated lithium-ion through the channel of zwitterion groups is proposed. The polySH electrolyte-based-supercapacitor (SC) exhibits a high specific capacitance of 178 mF cm −2 at 60 °C and 134 mF cm −2 at −30 °C with a retention of 81% and 71% of the initial capacitance after 10 000 cycles, respectively. The overall merits of the electrolyte will open up a new avenue for advanced ionic conductors and energy storage device in practical applications.
Magnetic separation with composite microspheres presents an alternative strategy for applications in biomedical and bioengineering fields. However, the synthesis of core-shell structured magnetic composites universally assumes the surfactant-directing and/or silica-assisting polymerization approach to modify and stabilize the magnetic cores. In this paper, we report on the surfactant-free synthesis of well-defined core-shell structured Fe(3)O(4)@PANI and Fe(3)O(4)@PPy microspheres with high magnetization. The temperature dependence of magnetization of the samples was examined as a function of temperature between 3 and 300 K in an applied field of 500 Oe. It was found that the blocking temperature (T(B)) values of the composite spheres are well above the room temperature. The small variation in magnetization as the temperature changes renders the composite spheres a suitable candidate when used at elevated temperatures. Also, the genomic DNA can be effectively isolated from Aspergillus niger (A. niger) cells with the composite microspheres, using a PEG-NaCl binding buffer and a phosphate eluting buffer. The magnetic isolation of genomic DNA with the composite microspheres was shown to be superior to the conventional phenol-chloroform extraction, which was confirmed by agarose gel eletrophoresis and polymerase chain reaction (PCR) diagnosis. The Fe(3)O(4)@PANI and Fe(3)O(4)@PPy microspheres presented here have great potential in enzyme immobilization, drug delivery, catalysis, and sensors.
An integrated structure has been designed by grafting the polymer of polybromopyrroles (PPBP) onto reduced graphene oxide (RGO) to produce RGO/PPBP nanocomposites with superior electrochemical performance for supercapacitors.
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