Disclosed are a polymer electrolyte membrane having high flexibility, high ionic conductivity, and excellent mechanical durability, a method for manufacturing same, and an electrochemical device comprising same. The polymer electrolyte membrane of the present invention comprises a polymer electrolyte material, wherein the polymer electrolyte material comprises: an ion conductor having an ion-exchange group; and an organic compound which binds to the ion-exchange group via an ionic bond or a hydrogen bond, thereby allowing the polymer electrolyte material to have an ionic crosslink structure or a hydrogen bond crosslink structure.

A separator including a porous base and a coating layer on at least one surface of the porous base, the coating layer including (a) a carbon nanotube including an oxygen functional group and (b) a lithium ion conducting polymer, and a lithium-sulfur battery including the same. Such a separator may be capable of resolving problems caused by lithium polysulfide occurring in a lithium-sulfur battery.

The present disclosure describes various types of batteries, including lithium-ion batteries having an anode assembly comprising: an anode comprising a first porous ceramic matrix having pores; and a ceramic separator layer affixed directly or indirectly to the anode; a cathode; an anode-side current collector contacting the anode; and anode active material comprising lithium located within the pores or cathode active material located within the cathode; wherein, the ceramic separator layer is located between the anode and the cathode, no electrically conductive coating on the pores contacts the separator layer, and in a fully charged state, lithium active material in the anode does not contact the separator layer. Also disclosed are methods of making and methods of using such batteries.

The present disclosure relates to a polymer electrolyte membrane for medium and high temperature, a preparation method thereof and a high-temperature polymer electrolyte membrane fuel cell including the same, more particularly to a technology of preparing a composite membrane including an inorganic phosphate nanofiber incorporated into a phosphoric acid-doped polybenzimidazole (PBI) polymer membrane by adding an inorganic precursor capable of forming a nanofiber in a phosphoric acid solution when preparing phosphoric acid-doped polybenzimidazole and using the same as a high-temperature polymer electrolyte membrane which is thermally stable even at high temperatures of 200-300° C. without degradation of phosphoric acid and has high ion conductivity.

A hybrid solid electrolyte particulate for use in a rechargeable lithium battery cell, wherein said particulate comprises one or more than one inorganic solid electrolyte particles encapsulated by a shell of elastic polymer electrolyte wherein (i) the hybrid solid electrolyte particulate has a lithium-ion conductivity from 10.sup.−6 S/cm to 5×10.sup.−2 S/cm and both the inorganic solid electrolyte and the elastic polymer electrolyte individually have a lithium-ion conductivity no less than 10.sup.−6 S/cm; (ii) the elastic polymer electrolyte-to-inorganic solid electrolyte ratio is from 1/100 to 100/1 or the elastic polymer electrolyte shell has a thickness from 1 nm to 10 μm; and (iii) the elastic polymer electrolyte has a recoverable elastic tensile strain from 5% to 1,000%. Also provided is a lithium-ion or lithium metal cell containing multiple hybrid solid electrolyte particulates in the anode, cathode and/or the separator. Processes for producing hybrid solid electrolyte particulates are also disclosed.

The present disclosure describes a lithium solid state battery, including a cathode that includes an active material such as lithium, and an additive having a lower melting point than the active material. The additive can provide a composite cathode where a cathode-electrolyte interphase has high electronic and ionic conductivity, good mechanical deformability, and high oxidation potential.

A hybrid solid electrolyte particulate for use in a rechargeable lithium battery cell, wherein said particulate comprises one or more than one inorganic solid electrolyte particles encapsulated by a shell of conducting polymer electrolyte wherein (i) the hybrid solid electrolyte particulate has a lithium-ion conductivity from 10.sup.−6 S/cm to 5×10.sup.−2 S/cm and both the inorganic solid electrolyte and the conducting polymer electrolyte individually have a lithium-ion conductivity no less than 10.sup.−6 S/cm; (ii) the conducting polymer electrolyte has an electron conductivity no less than 10.sup.−6 S/cm; and (iii) the conducting polymer electrolyte-to-inorganic solid electrolyte ratio is from 1/100 to 100/1 or the conducting polymer electrolyte shell has a thickness from 1 nm to 10 μm. Also provided is a lithium-ion or lithium metal cell containing multiple hybrid solid electrolyte particulates in the anode and/or the cathode. Processes for producing hybrid solid electrolyte particulates are also disclosed.

A polymer solid electrolyte having high ion conductivity, heat resistance and dimensional stability, and having excellent oxidation stability and voltage stability, and a lithium secondary battery including the same.

A method for making a lithium foil anode of an all-solid-state lithium battery includes the steps of: a) dispersing a carbon nanomaterial in water to form a dispersion; b) mixing dopamine with the dispersion so as to permit the dopamine to perform a polymerization reaction in the dispersion to obtain a surface-modified carbon nanomaterial which is surface-modified by polydopamine; c) forming a regular sub-millimeter textured structure on a lithium foil; d) mixing the surface-modified carbon nanomaterial with a lithium ion-containing polymer to form a mixture; and e) applying the mixture on the lithium foil.

The present disclosure provides a method for forming a solid-state battery. The method includes stacking two or more cell units, where each cell unit is formed by substantially aligning a first electrode and a second electrode, where the first electrode includes one or more first electroactive material layers disposed on or adjacent to one or more surfaces of a releasable substrate and the second electrode includes one or more second electroactive material layers disposed on or adjacent to one or more surfaces of a current collector; disposing an electrolyte layer between exposed surfaces of the first electrode and the second electrode; and removing the releasable substrate to form the cell unit.