Abstract: Particular embodiments may provide a lithium-ion battery comprising a MAX compound to prevent and/or decrease Manganese dissolution. In some embodiments, the MAX compound comprises the formula Mn+1AXn, wherein M is an early transition metal atom, n is an integer from 1 to 3, A is a group 13 or group 14 element, and X is C or N.

Abstract: Provided are battery cells comprising: a lithiophilic electrode; and a liquid electrolyte, wherein the battery cell has an N/P ratio of less than 1.0. In some embodiments, the multilayer lithiophilic electrode comprises a first layer comprising predominantly active material and a second layer comprising predominantly lithiophilic material. Other materials used in the first and second layers can include a binder and/or a conducting agent.

Abstract: An electrode includes an electrode active material and a lithium generating species including a mixture of Li3N and MNx, wherein MNx is a metal nitride including a metal (M) selected from Na, K, Ca, Mg, Ba, V, Nb, Ti, Zr, and Sr, or a mixture of any two or more thereof.

Abstract: Solid state compositions for use in an anode of a secondary battery, anodes, and lithium ion batteries are provided which include silicon carbide nanofibers, preferably carried in and reinforcing both an anode active material and a solid electrolyte. Methods of production and use are further described.

Abstract: Secondary batteries which include embedded silicon carbide nanofibers are described and provided. Methods of production of the materials for use in the secondary batteries are further described.

Abstract: Compositions for use in an anode of a secondary battery, anodes, and lithium ion batteries are provided which include embedded silicon carbide nanofibers. Methods of production and use are further described.

Abstract: Solid state compositions for use in an anode of a secondary battery, anodes, and lithium ion batteries are provided which include silicon carbide nanofibers, preferably carried in and reinforcing both an anode active material and a solid electrolyte. Methods of production and use are further described.

Abstract: A rechargeable battery cell has an organic-liquid electrolyte contacting a dendrite free alkali-metal anode. The alkali-metal anode may be a liquid at the operating temperature that is immobilized by absorption into a porous membrane. The alkali-metal anode may be a solid that wets a porous-membrane separator, where the contact between the solid alkali-metal anode and the liquid electrolyte is at micropores or nanopores in the porous-membrane separator. The use of a dendrite-free solid lithium cell was demonstrated in a symmetric cell with a porous cellulose-based separator membrane. A K+-ion rechargeable cell was demonstrated with a liquid K—Na alloy anode immobilized in a porous carbon membrane using an organic-liquid electrolyte with a Celgard® or glass-fiber separator.

Abstract: A rechargeable battery cell has an organic-liquid electrolyte contacting a dendrite free alkali-metal anode. The alkali-metal anode may be a liquid at the operating temperature that is immobilized by absorption into a porous membrane. The alkali-metal anode may be a solid that wets a porous-membrane separator, where the contact between the solid alkali-metal anode and the liquid electrolyte is at micropores or nanopores in the porous-membrane separator. The use of a dendrite-free solid lithium cell was demonstrated in a symmetric cell with a porous cellulose-based separator membrane. A K+-ion rechargeable cell was demonstrated with a liquid K—Na alloy anode immobilized in a porous carbon membrane using an organic-liquid electrolyte with a Celgard® or glass-fiber separator.