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Progress in preparation, processing and applications of polyaniline

Recent developments in cathode materials for lithium ion batteries

Poly(ethylene oxide) (PEO) based materials are widely considered as promising candidates of polymer hosts in solid-state electrolytes for high energy density secondary lithium batteries. They have several specific advantages such as high safety, easy fabrication, low cost, high energy density, good electrochemical stability, and excellent compatibility with lithium salts. However, the typical linear PEO does not meet the production requirement because of its insufficient ionic conductivity due to the high crystallinity of the ethylene oxide (EO) chains, which can restrain the ionic transition due to the stiff structure especially at low temperature. Scientists have explored different approaches to reduce the crystallinity and hence to improve the ionic conductivity of PEO-based electrolytes, including blending, modifying and making PEO derivatives. This review is focused on surveying the recent developments and issues concerning PEO-based electrolytes for lithium-ion batteries.

Poly(ethylene oxide)-based electrolytes for lithium-ion batteries

A review on the separators of liquid electrolyte Li-ion batteries

Photocured PEO-based solid polymer electrolyte and its application to lithium-polymer batteries

Lithium-oxygen (Li-O2) batteries are desirable for electric vehicles because of their high energy density. Li dendrite growth and severe electrolyte decomposition on Li metal are, however, challenging issues for the practical application of these batteries. In this connection, an electrochemically active two-dimensional phosphorene-derived lithium phosphide is introduced as a Li metal protective layer, where the nanosized protective layer on Li metal suppresses electrolyte decomposition and Li dendrite growth. This suppression is attributed to thermodynamic properties of the electrochemically active lithium phosphide protective layer. The electrolyte decomposition is suppressed on the protective layer because the redox potential of lithium phosphide layer is higher than that of electrolyte decomposition. Li plating is thermodynamically unfavorable on lithium phosphide layers, which hinders Li dendrite growth during cycling. As a result, the nanosized lithium phosphide protective layer improves the cycle p...

Two-Dimensional Phosphorene-Derived Protective Layers on a Lithium Metal Anode for Lithium-Oxygen Batteries

Electrochemical properties of polyaniline doped with poly(styrenesulfonic acid)

Solid polymer electrolytes based on cross-linked polysiloxane- g-oligo(ethylene oxide): ionic conductivity and electrochemical properties

The mechanism of the protectivity of aluminum and supersaturated aluminum alloys containing W, Mo, Ta and Cu has been investigated in chloride environments. The potential of zero charge (PZC) of the passive film was evaluated by a method based on impedance spectroscopy. The chloride ion adsorption on the passive film was measured by means of an in situ radiotracer technique. Constituents of the passive film as a function of depth were investigated by means of ex situ spectroscopic techniques including XPS, ISS and SIMS. The PZCs of the passive films of Al and Al alloys were calculated from the flatband potentials. A linear correlation between pitting potential and the PZC was found. Adsorption of the chloride ion on the Al-Ta surface starts at more anodic potentials than those of pure Al, and this shift is in agreement with the anodic shift of the PZC. A constant surface concentration of chloride ion was observed during the induction time for breakdown. A significant de crease of OH− concentration in the passive film of Al and its alloys has been found after the passive film has undergone breakdown. The mole fraction of the alloying elements in the surface region of the passive film is ca. 1–8%. The adsorption of the chloride ion on the surface of the passive film is influenced by the anodic PZC shift, which varies with the alloying element. However, retardation of the chloride penetration into the passive film by blocking of the entry site by oxide ions of the alloying element controls the rate of breakdown.

Yongku Kang

Papers

Photocured PEO-based solid polymer electrolyte and its application to lithium-polymer batteries

Two-Dimensional Phosphorene-Derived Protective Layers on a Lithium Metal Anode for Lithium-Oxygen Batteries

Electrochemical properties of polyaniline doped with poly(styrenesulfonic acid)

Solid polymer electrolytes based on cross-linked polysiloxane- g-oligo(ethylene oxide): ionic conductivity and electrochemical properties

The protectivity of aluminum and its alloys with transition metals