Abstract: An ion-conducting composite electrolyte is provided comprising path-engineered ion-conducting ceramic electrolyte particles and a solid polymeric matrix. The path-engineered particles are characterized by an anisotropic crystalline structure and the ionic conductivity of the crystalline structure in a preferred conductivity direction H associated with one of the crystal planes of the path-engineered particle is larger than the ionic conductivity of the crystalline structure in a reduced conductivity direction L associated with another of the crystal planes of the path-engineered particle. The path-engineered particles are sized and positioned in the polymeric matrix such that a majority of the path-engineered particles breach both of the opposite major faces of the matrix body and are oriented in the polymeric matrix such that the preferred conductivity direction H is more closely aligned with a minimum path length spanning a thickness of the matrix body than is the reduced conductivity direction L.

Abstract: Glass articles for use as covers in electronic devices and methods for forming the same are described herein. The glass articles generally include a shaped glass substrate comprising a first face, a second face and a perimeter edge. The shaped glass substrate may be formed from strengthened glass such that the shaped glass substrate has a compressive stress layer which improves the ability of the glass article to withstand surface damage without cracking. A polymer overmold is coupled to the attachment feature of the perimeter edge of the shaped glass substrate thereby protecting the perimeter edge of the shaped glass substrate from damage. In one embodiment, at least a portion of the perimeter edge of the shaped glass substrate comprises an attachment feature offset from the first face. In another embodiment the polymer overmold is integrally formed with at least one connector.

Abstract: An ion-conducting composite electrolyte is provided comprising path-engineered ion-conducting ceramic electrolyte particles and a solid polymeric matrix. The path-engineered particles are characterized by an anisotropic crystalline structure and the ionic conductivity of the crystalline structure in a preferred conductivity direction H associated with one of the crystal planes of the path-engineered particle is larger than the ionic conductivity of the crystalline structure in a reduced conductivity direction L associated with another of the crystal planes of the path-engineered particle. The path-engineered particles are sized and positioned in the polymeric matrix such that a majority of the path-engineered particles breach both of the opposite major faces of the matrix body and are oriented in the polymeric matrix such that the preferred conductivity direction H is more closely aligned with a minimum path length spanning a thickness of the matrix body than is the reduced conductivity direction L.

Abstract: Particle-loaded fibers include a fiber body having inorganic particles bound together by an organic binder. The fiber body has a diameter less than about 150 ?m, and the inorganic particles comprise a particle density of greater than 20%, 30%, 40% or even 50% by volume of the fiber body. Methods for producing such particle loaded fibers include extruding a composition through a die orifice having a diameter of less than 1000 ?m to form a fiber having a first diameter, and drawing the fiber from the first diameter to a smaller second diameter of less than 150 ?m, wherein the inorganic particles are greater than 50% by weight of the extruded composition.

Abstract: Glass articles for use as covers in electronic devices and methods for forming the same are described herein. The glass articles generally include a shaped glass substrate comprising a first face, a second face and a perimeter edge. The shaped glass substrate may be formed from strengthened glass such that the shaped glass substrate has a compressive stress layer which improves the ability of the glass article to withstand surface damage without cracking. A polymer overmold is coupled to the attachment feature of the perimeter edge of the shaped glass substrate thereby protecting the perimeter edge of the shaped glass substrate from damage. In one embodiment, at least a portion of the perimeter edge of the shaped glass substrate comprises an attachment feature offset from the first face. In another embodiment the polymer overmold is integrally formed with at least one connector.