Proposed is a new sulfide-based solid electrolyte for lithium ion batteries, the sulfide-based solid electrolyte relating to a compound that has a cubic argyrodite type crystal structure and is represented by Li.sub.7-x-2yPS.sub.6-x-yCl.sub.x, and having excellent water resistance and oxidation resistance. Proposed is a sulfide-based solid electrolyte for lithium ion batteries, the sulfide-based solid electrolyte containing a compound that has a cubic argyrodite type crystal structure and is represented by compositional formula (1) : Li.sub.7-x-2yPS.sub.6-x-yCl.sub.x, in which compositional formula, conditions: 0.8 ≦x≦1.7 and 0<y≦−0.25x+0.5 are satisfied.

A solid electrolyte powder includes ion-conductive LATP powder that is obtained by heating and melting raw materials at a predetermined temperature to prepare molten LATP mixture, cooling the molten LATP mixture to prepare a crystalline material having a NASICON structure, crushing the crystalline material to prepare crystal powder having a particle size of 1 μm to 10 μm, and performing a heat treatment on the crystal powder in air at a temperature of 800° C. to 1000° C. for a predetermined period of time.

A suspended-particle device with improved adhesion between the active and conductive layers is disclosed. The conductive layers are coated with an adhesion promoter that comprises at least one organosilane that covalently bonds to the surface of the conductive layer and comprises a cross-linkable moiety such as an acrylate. The active layer comprises a suspension of active particles in a polymer matrix that comprises a polymer having pendant cross-linkable moieties such as acrylates. Upon curing (e.g. by irradiation by ultraviolet light), the polymer matrix of the active layer cross-links with the cross-linkable moieties of the adhesion promoter, thereby binding the active and conductive layers.

A solid electrolyte material according to an aspect of the present disclosure is represented by the following Compositional Formula (1):
Li.sub.6-3zY.sub.zX.sub.6
where, 0<z<2 is satisfied; and X represents Cl or Br.

A solid electrolyte material according to an aspect of the present disclosure is represented by the following Compositional Formula (1):
Li.sub.6-3zY.sub.zX.sub.6
where, 0<z<2 is satisfied; and X represents Cl or Br.

The present invention pertains to a glass characterized by: containing 72-82% of Li.sup.+, 0-21% of Si.sup.4+, and 0-28% of B.sup.3+ in terms of cation %; and containing at least 70% and less than 100% of O.sup.2− and more than 0% and at most 30% of Cl.sup.−, containing at least 94% and less than 100% of O.sup.2− and more than 0% and at most 6% of S.sup.2−, or containing at least 64% and less than 100% of O.sup.2−, more than 0% and at most 30% of Cl.sup.−, and more than 0% and at most 6% of S.sup.2−, in terms of anion %.

The present invention pertains to a glass characterized by: containing 72-82% of Li.sup.+, 0-21% of Si.sup.4+, and 0-28% of B.sup.3+ in terms of cation %; and containing at least 70% and less than 100% of O.sup.2− and more than 0% and at most 30% of Cl.sup.−, containing at least 94% and less than 100% of O.sup.2− and more than 0% and at most 6% of S.sup.2−, or containing at least 64% and less than 100% of O.sup.2−, more than 0% and at most 30% of Cl.sup.−, and more than 0% and at most 6% of S.sup.2−, in terms of anion %.

Disclosed herein is a composite comprising a conductive elastomer and an isolating elastomer. When a current is passed through the conductive elastomer, its tensile modulus decreases as the elastomer heats from internal Joule heating, changing the rigidity of the composite. When the current is no longer present, the elastomer cools and the rigidity of the composite returns to its original state.

Disclosed herein is a composite comprising a conductive elastomer and an isolating elastomer. When a current is passed through the conductive elastomer, its tensile modulus decreases as the elastomer heats from internal Joule heating, changing the rigidity of the composite. When the current is no longer present, the elastomer cools and the rigidity of the composite returns to its original state.

Provided is a cathode active material including a core including a compound represented by Formula 1; and a coating layer including a phosphorus-containing compound disposed on a surface of the core:
Li.sub.aZr.sub.αW.sub.βM.sub.1−α−βO.sub.2−bS.sub.b  Formula 1 In Formula 1, M, Zr, W, a, α, β, and b are the same as defined in relation to the present specification.