An anode compartment for rechargeable lithium or sodium batteries, including: a solid electrolyte; a collector deposited on the solid electrolyte; and an active material made of lithium metal or sodium metal which has been grown between the solid electrolyte and the collector in order to form an electrode made of lithium metal or sodium metal with the collector, in which the collector is made of an amorphous alloy. A method for manufacturing such an anode compartment and a battery including said anode compartment is also presented.

An electroplating apparatus includes a container containing plural portions and an ionic liquid plating solution that is capable of flowing therebetween. The plural portions include at least a first portion containing a counter electrode that includes coating donor material and a second portion that includes a workpiece. A porous scrubber separating the first and second portions has a plurality of metallic outer surfaces in contact with the ionic liquid plating solution. Coating, repair, and regeneration methods using an ionic liquid plating solution are also described.

An electroplating apparatus includes a container containing plural portions and an ionic liquid plating solution that is capable of flowing therebetween. The plural portions include at least a first portion containing a counter electrode that includes coating donor material and a second portion that includes a workpiece. A porous scrubber separating the first and second portions has a plurality of metallic outer surfaces in contact with the ionic liquid plating solution. Coating, repair, and regeneration methods using an ionic liquid plating solution are also described.

Disclosed are novel electrolytes, and techniques for making and devices using such electrolytes, which are based on compressed-gas solvents. Unlike conventional electrolytes, the disclosed electrolytes are based on compressed-gas solvents mixed with various salts, referred to as compressed gas electrolytes. Various embodiments of a compressed-gas solvent includes a material that is in a gas phase and has a vapor pressure above atmospheric pressure at a room temperature. The disclosed compressed-gas electrolytes can have wide electrochemical potential windows, high conductivity, low temperature capability and/or high-pressure solvent properties. Examples of a class of compressed gases that can be used as solvent for electrolytes include hydrofluorocarbons, in particular fluoromethane, difluoromethane, tetrafluoroethane, and pentafluoroethane. Also disclosed are battery structures and supercapacitor structures that use compressed gas solvent-based electrolytes, and techniques for constructing such energy storage devices. Techniques for electroplating difficult-to-deposit materials using compressed-gas electrolytes as an electroplating bath are also disclosed.

Disclosed are novel electrolytes, and techniques for making and devices using such electrolytes, which are based on compressed-gas solvents. Unlike conventional electrolytes, the disclosed electrolytes are based on compressed-gas solvents mixed with various salts, referred to as compressed gas electrolytes. Various embodiments of a compressed-gas solvent includes a material that is in a gas phase and has a vapor pressure above atmospheric pressure at a room temperature. The disclosed compressed-gas electrolytes can have wide electrochemical potential windows, high conductivity, low temperature capability and/or high-pressure solvent properties. Examples of a class of compressed gases that can be used as solvent for electrolytes include hydrofluorocarbons, in particular fluoromethane, difluoromethane, tetrafluoroethane, and pentafluoroethane. Also disclosed are battery structures and supercapacitor structures that use compressed gas solvent-based electrolytes, and techniques for constructing such energy storage devices. Techniques for electroplating difficult-to-deposit materials using compressed-gas electrolytes as an electroplating bath are also disclosed.

Electrolytic systems and methods are described for extracting lithium ions from a brine and depositing onto a conductive substrate to form purified lithium and lithium alloys suitable for use in lithium metal batteries. The methods allow for selective extraction of lithium ions and electroplating the extracted lithium ions as lithium metal and lithium metal alloys.

A battery pre-lithiation assembly includes an enclosure and an electrode disposed in the enclosure. The electrode assembly includes a current collector, active material disposed on the current collector, and perforations extending through the active material and the current collector. The battery pre-lithiation assembly also includes a lithium metal coating on an interior of the enclosure. The perforations are configured to enable migration of Li+ ions from the lithium metal coating to the electrode via a pre-lithiation process when the enclosure receives an electrolyte.

A battery pre-lithiation assembly includes an enclosure and an electrode disposed in the enclosure. The electrode assembly includes a current collector, active material disposed on the current collector, and perforations extending through the active material and the current collector. The battery pre-lithiation assembly also includes a lithium metal coating on an interior of the enclosure. The perforations are configured to enable migration of Li+ ions from the lithium metal coating to the electrode via a pre-lithiation process when the enclosure receives an electrolyte.

Disclosed are novel electrolytes, and techniques for making and devices using such electrolytes, which are based on compressed gas solvents. Unlike conventional electrolytes, disclosed electrolytes are based on compressed gas solvents mixed with various salts, referred to as compressed gas electrolytes. Various embodiments of a compressed gas solvent include a material that is in a gas phase and has a vapor pressure above an atmospheric pressure at room temperature. The disclosed compressed gas electrolytes can have wide electrochemical potential windows, high conductivity, low temperature capability and/or high pressure solvent properties. Examples of a class of compressed gases that can be used as solvent for electrolytes include hydrofluorocarbons, in particular fluoromethane, difluoromethane, tetrafluoroethane, and pentafluoroethane. Also disclosed are battery and supercapacitor structures that use compressed gas solvent-based electrolytes and techniques for constructing such energy storage devices. Techniques for electroplating difficult-to-deposit materials using compressed gas electrolytes as an electroplating bath are also disclosed.

Disclosed are novel electrolytes, and techniques for making and devices using such electrolytes, which are based on compressed gas solvents. Unlike conventional electrolytes, disclosed electrolytes are based on compressed gas solvents mixed with various salts, referred to as compressed gas electrolytes. Various embodiments of a compressed gas solvent include a material that is in a gas phase and has a vapor pressure above an atmospheric pressure at room temperature. The disclosed compressed gas electrolytes can have wide electrochemical potential windows, high conductivity, low temperature capability and/or high pressure solvent properties. Examples of a class of compressed gases that can be used as solvent for electrolytes include hydrofluorocarbons, in particular fluoromethane, difluoromethane, tetrafluoroethane, and pentafluoroethane. Also disclosed are battery and supercapacitor structures that use compressed gas solvent-based electrolytes and techniques for constructing such energy storage devices. Techniques for electroplating difficult-to-deposit materials using compressed gas electrolytes as an electroplating bath are also disclosed.