An energy storage device can include a cathode, an anode, and a separator between the cathode and the anode, where the anode and/or electrode includes an electrode film having a super-fibrillized binder material and carbon. The electrode film can have a reduced quantity of the binder material while maintaining desired mechanical and/or electrical properties. A process for fabricating the electrode film may include a fibrillization process using reduced speed and/or increased process pressure such that fibrillization of the binder material can be increased. The electrode film may include an electrical conductivity promoting additive to facilitate decreased equivalent series resistance performance. Increasing fibrillization of the binder material may facilitate formation of thinner electrode films, such as dry electrode films.

An energy storage device can include a cathode, an anode, and a separator between the cathode and the anode, where the anode and/or electrode includes an electrode film having a super-fibrillized binder material and carbon. The electrode film can have a reduced quantity of the binder material while maintaining desired mechanical and/or electrical properties. A process for fabricating the electrode film may include a fibrillization process using reduced speed and/or increased process pressure such that fibrillization of the binder material can be increased. The electrode film may include an electrical conductivity promoting additive to facilitate decreased equivalent series resistance performance. Increasing fibrillization of the binder material may facilitate formation of thinner electrode films, such as dry electrode films.

An embodiment is directed to an electrode composition for use in an energy storage device cell. The electrode comprises composite particles, each comprising carbon that is biomass-derived and active material. The active material exhibits partial vapor pressure below around 10.sup.−13 torr at around 400 K, and an areal capacity loading of the electrode composition ranges from around 2 mAh/cm.sup.2 to around 16 mAh/cm.sup.2.

A hydraulic binder includes at least 70% by weight of a solid mineral compound consisting of at least one mixture of silica, alumina and alkaline-earth metal oxides, the total sum of CaO and MgO representing at least 10% by weight of the solid mineral compound, and an activation system of which at least 30% by weight is a phosphoric acid-derived salt. Construction products can obtained from a mortar composition including such a binder.

A nanocomposite is provided. The nanocomposite includes an electrically conductive nanostructured material; and metal fluoride nanostructures having the general formula M.sup.(I).sub.xM.sup.(II).sub.1−xF.sub.2+y−zn arranged on the electrically conductive nanostructured material, wherein M.sup.(I) and M.sup.(II) are independently transition metals, n is a stoichiometric coefficient, and wherein i) x=0, 0<y≦2, and z=0; or ii) 0<x<1, 0≦y≦2, z≧0, and M.sup.(I) and M.sup.(II) are different transition metals. An electrode including the nanocomposite and method of preparing the nanocomposite are also provided.

A nanocomposite is provided. The nanocomposite includes an electrically conductive nanostructured material; and metal fluoride nanostructures having the general formula M.sup.(I).sub.xM.sup.(II).sub.1−xF.sub.2+y−zn arranged on the electrically conductive nanostructured material, wherein M.sup.(I) and M.sup.(II) are independently transition metals, n is a stoichiometric coefficient, and wherein i) x=0, 0<y≦2, and z=0; or ii) 0<x<1, 0≦y≦2, z≧0, and M.sup.(I) and M.sup.(II) are different transition metals. An electrode including the nanocomposite and method of preparing the nanocomposite are also provided.

A negative active material includes a carbon material. The carbon material satisfies the following relationship: 6<Gr/K<16, Gr is a graphitization degree of the carbon material, measured by means of X-ray diffraction; and K is a ratio Id/Ig of a peak intensity Id of the carbon material at a wavenumber of 1250 cm.sup.−1 to 1650 cm.sup.−1 to a peak intensity Ig of the carbon material at a wavenumber of 1500 cm.sup.−1 to 1650 cm.sup.−1, and is measured by using Raman spectroscopy, and K is 0.06 to 0.15. The negative active material according to this application can significantly improve an energy density, cycle performance, and rate performance of the electrochemical device.

A method is for producing electrochemical energy storage devices utilizing lithium and for producing materials used in the devices, such that the anode has lithium metal, inorganic solid electrolytes. Anode and cathode components are joined together by pressure and/or temperature utilized in the production. The lithium-metal layer is produced at least partly by a pulsed laser deposition method. The method can utilise various inorganic solid electrolytes produced by different methods and a roll-to-roll method as well as different ways to couple pressure and/or temperature to the component being processed.

To provide a non-aqueous electrolyte electricity-storage element including a positive electrode including a positive-electrode active material capable of inserting and releasing anions, a negative electrode including a negative-electrode active material capable of inserting and releasing cations, and a non-aqueous electrolyte, wherein the positive-electrode active material is porous carbon having pores having a three-dimensional network structure, and wherein a changing rate of a cross-sectional thickness of a positive electrode film including the positive-electrode active material defined by Formula (1) below is less than 45%.

The present application is generally directed to composites comprising a hard carbon material and an electrochemical modifier. The composite materials find utility in any number of electrical devices, for example, in lithium ion batteries. Methods for making the disclosed composite materials are also disclosed.