A mixed conductor represented by Formula 1:
A.sub.4+xM.sub.5-yM′.sub.yO.sub.12-δ,  Formula 1
wherein, in Formula 1, A is a monovalent cation, M is at least one of a divalent cation, a trivalent cation, or a tetravalent cation, M′ is at least one of a monovalent cation, a divalent cation, a trivalent cation, a tetravalent cation, a pentavalent cation, or a hexavalent cation, M and M′ are different from each other, and 0.3≤x<3, 0.01<y<2, and 0≤δ≤1 are satisfied.

Provided is a metal-air battery including a cathode having a space which may be filled with a metal oxide formed during a discharge of the metal-air battery and thus having improved energy density and lifespan. The cathode for the metal-air battery includes a plurality of cathode materials, a plurality of electrolyte films disposed on surfaces of the plurality of cathode materials, and a plurality of spaces which are not occupied by the plurality of cathode materials and the plurality of electrolyte films. A volume of the plurality of spaces may be greater than or equal to a maximum space of a metal oxide formed during a discharge of the metal-air battery.

An electrochemical energy storage device includes an anode having a first mixture which includes a first plurality of electrically conductive carbon-comprising particles having a first average porosity, and lithium metal materials. The weight ratio of the first plurality of carbon-comprising and lithium metal materials is from 30:1 to 3:1. A cathode includes a second mixture having a second plurality of electrically conductive carbon-comprising particles having a second average porosity greater than the first average porosity, and lithium-intercalating metal oxide particles. The weight ratio of the second plurality of carbon-comprising and lithium-intercalating metal oxide particles is from 1:20 to 5:1. The weight ratio between the lithium metal materials loaded in the anode and the second plurality of carbon-comprising particles in the cathode is from 0.1-10%. An electrolyte physically and ionically contacts the anode and the cathode, and fills the pore volume in the anode, cathode and a porous separator.

An electrochemical energy storage device includes an anode having a first mixture which includes a first plurality of electrically conductive carbon-comprising particles having a first average porosity, and lithium metal materials. The weight ratio of the first plurality of carbon-comprising and lithium metal materials is from 30:1 to 3:1. A cathode includes a second mixture having a second plurality of electrically conductive carbon-comprising particles having a second average porosity greater than the first average porosity, and lithium-intercalating metal oxide particles. The weight ratio of the second plurality of carbon-comprising and lithium-intercalating metal oxide particles is from 1:20 to 5:1. The weight ratio between the lithium metal materials loaded in the anode and the second plurality of carbon-comprising particles in the cathode is from 0.1-10%. An electrolyte physically and ionically contacts the anode and the cathode, and fills the pore volume in the anode, cathode and a porous separator.

Provided is a metal-air battery including a cathode having a space which may be filled with a metal oxide formed during a discharge of the metal-air battery and thus having improved energy density and lifespan. The cathode for the metal-air battery includes a plurality of cathode materials, a plurality of electrolyte films disposed on surfaces of the plurality of cathode materials, and a plurality of spaces which are not occupied by the plurality of cathode materials and the plurality of electrolyte films. A volume of the plurality of spaces may be greater than or equal to a maximum space of a metal oxide formed during a discharge of the metal-air battery.

A hybrid lithium-ion battery/capacitor cell (10) comprising at least a pair of graphite anodes (14,18) assembled with a lithium compound cathode (12) and an activated carbon capacitor electrode (16) can provide useful power performance properties and low temperature properties required for many power-utilizing applications. The initial formation of the graphite anodes (14,18) of this hybrid cell (10) combination is enhanced by including particles of a selected lithium compound with the activated carbon particles used in forming the capacitor electrode(16). The composition of the lithium compound is selected to produce lithium ions in the liquid electrolyte of the assembled cell (10) to enhance the in-situ lithiation of the graphite particles of the anodes (14,18) during formation cycles of the assembled hybrid cell (10).

A hybrid lithium-ion battery/capacitor cell (10) comprising at least a pair of graphite anodes (14,18) assembled with a lithium compound cathode (12) and an activated carbon capacitor electrode (16) can provide useful power performance properties and low temperature properties required for many power-utilizing applications. The initial formation of the graphite anodes (14,18) of this hybrid cell (10) combination is enhanced by including particles of a selected lithium compound with the activated carbon particles used in forming the capacitor electrode(16). The composition of the lithium compound is selected to produce lithium ions in the liquid electrolyte of the assembled cell (10) to enhance the in-situ lithiation of the graphite particles of the anodes (14,18) during formation cycles of the assembled hybrid cell (10).

The present disclosure relates to a pliable carbonaceous pocket composite structure including various particles encapsulated within pliable carbonaceous pockets formed by carbonaceous sheets, a method for preparing the pliable carbonaceous pocket composite structure which enables ultrafast mass production of the pliable carbonaceous pocket composite structure, an electrode including the pliable carbonaceous pocket composite structure, and an energy storage device including the electrode.

The present disclosure relates to a pliable carbonaceous pocket composite structure including various particles encapsulated within pliable carbonaceous pockets formed by carbonaceous sheets, a method for preparing the pliable carbonaceous pocket composite structure which enables ultrafast mass production of the pliable carbonaceous pocket composite structure, an electrode including the pliable carbonaceous pocket composite structure, and an energy storage device including the electrode.

An energy distribution system. The energy distribution system has a housing with a rear terminal and a front terminal. An inlet unit receives air therethrough. The inlet unit then passes the air through a one-way valve into a reservoir where the air molecules undergo ionization. Once ionized, the gaseous air is converted into a plasma state. After being converted into the plasma state, electric energy is generated by a pair of magnets and stored in a capacitor.