The disclosure provides a method of prelithiating an anode for a lithium-ion cell, the method comprising: (a) providing a pre-fabricated anode comprising an anode active material; (b) prelithiating the pre-fabricated anode by exposing the anode to a lithium source and an electrolyte solution, comprising a lithium salt dissolved in a liquid solvent, to enable lithium ions to intercalate into the anode active material until a level of lithium interaction from 5% to 100% of the maximum lithium storage capacity is achieved to form a prelithiated anode; and (c) introducing a protective polymer onto the prelithiated anode to prevent exposure of the prelithiated anode active material to the open air or into the anode to bond the prelithiated anode active material or to improve a structural integrity of the prelithiated anode, wherein the protective polymer has a lithium-ion conductivity from 10.sup.−8 S/cm to 5×10.sup.−2 S/cm at room temperature.

An electrolyte for a lithium metal battery and a lithium metal battery including the same, more specifically an electrolyte for a lithium metal battery including a lithium salt, an organic solvent and an additive, wherein the additive includes a functional group that binds to lithium metal at one end thereof and a fluorinated hydrocarbon group at the other end. The electrolyte for the lithium metal battery includes an additive including particular functional groups to improve the stability of the lithium metal and suppress the side reaction at the surface, thereby enabling the lithium metal battery to have high capacity, high stability, and long life.

An electrolyte for a lithium metal battery and a lithium metal battery including the same, more specifically an electrolyte for a lithium metal battery including a lithium salt, an organic solvent and an additive, wherein the additive includes a functional group that binds to lithium metal at one end thereof and a fluorinated hydrocarbon group at the other end. The electrolyte for the lithium metal battery includes an additive including particular functional groups to improve the stability of the lithium metal and suppress the side reaction at the surface, thereby enabling the lithium metal battery to have high capacity, high stability, and long life.

The present invention relates to an electrochemical device comprising a) a positive electrode, b) a negative electrode, c) a separator, and d) a liquid electrolyte, wherein at least one of said positive electrode and said negative electrode is a gelled electrode comprising an electronic conductive substrate and directly adhered onto the electronic conductive substrate, at least one layer of a gelled electrode-forming composition, and wherein the d) liquid electrolyte comprises at least one organic carbonate and/or at least one ionic liquid, and at least one metal salt. The present invention also relates to a process for manufacturing an electrochemical device comprising at least one gelled electrode.

Electrochemical cells that incorporate a greenhouse gas, including an electrode that includes an electrode active material, an electrolyte including an electrolytic solvent, and a housing that encloses the electrode and electrolyte under a gaseous atmosphere including a greenhouse gas, where the electrolyte is in contact with the electrode, and the electrode active material has a solubility of at least 0.01 M in the electrolytic solvent.

Electrochemical cells that incorporate a greenhouse gas, including an electrode that includes an electrode active material, an electrolyte including an electrolytic solvent, and a housing that encloses the electrode and electrolyte under a gaseous atmosphere including a greenhouse gas, where the electrolyte is in contact with the electrode, and the electrode active material has a solubility of at least 0.01 M in the electrolytic solvent.

A cathode active material for a lithium secondary battery includes a lithium metal oxide particle, and an organic poly-phosphate or an organic poly-phosphonate formed on at least portion of a surface of the lithium metal oxide particle. Chemical stability of the lithium metal oxide particle may be improved and surface residues may be reduced by the organic poly-phosphate or the organic poly-phosphonate.

Provided is a negative electrode active material which includes: a silicon-based core; and an outer coating layer formed on the silicon-based core and including polyimide, wherein the polyimide comprises a fluorine-containing imide unit. The outer coating layer may be included in an amount of more than 0 wt % and 4.5 wt % or less in the negative electrode active material.

An iterative approach to dynamic covalent polymerizations of elemental sulfur with functional comonomers to prepare sulfur prepolymers that can further react with other conventional, commercially available comonomers to prepare a wider class of functional sulfur polymers. This iterative method improves handling, miscibility and solubility of the elemental sulfur, and further enables tuning of the sulfur polymer composition. The sulfur polymers may be a thermoplastic or a thermoset for use in elastomers, resins, lubricants, coatings, antioxidants, cathode materials for electrochemical cells, and polymeric articles such as polymeric films and free-standing substrates.

The present invention provides a method of producing sulfur-modified polyacrylonitrile, including: a step (1) of heating polyacrylonitrile and elemental sulfur in a rotating-type heating container including a discharge pipe and a sulfur vapor recovery unit while rotating the rotating-type heating container; a step (2) of liquefying a sulfur vapor by the sulfur vapor recovery unit while discharging hydrogen sulfide generated in the heating step; and a step (3) of returning the liquefied sulfur to a mixture of the sulfur and the polyacrylonitrile of the step (1).