Abstract: Additives to electrolytes that enable the formation of comparatively more robust SEI films on silicon anodes. The SEI films in these embodiments are seen to be more robust in part because the batteries containing these materials have higher coulombic efficiency and longer cycle life than comparable batteries without such additives. The additives preferably contain a nitrate group.

Abstract: Additives to electrolytes that enable the formation of comparatively more robust SEI films on silicon anodes. The SEI films in these embodiments are seen to be more robust in part because the batteries containing these materials have higher coulombic efficiency and longer cycle life than comparable batteries without such additives. The additives preferably contain a dicarbonate group or are an organo-metallic hydride.

Abstract: Described herein are additives for use in electrolytes that provide a number of desirable characteristics when implemented within batteries, such as high capacity retention during battery cycling at high temperatures. In some embodiments, a high temperature electrolyte includes a base electrolyte and one or more polymer additives, which impart these desirable performance characteristics.

Abstract: Additives to electrolytes that enable the formation of comparatively more robust SEI films on silicon anodes. The SEI films in these embodiments are seen to be more robust in part because the batteries containing these materials have higher coulombic efficiency and longer cycle life than comparable batteries without such additives. The additives preferably contain a nitrate group.

Abstract: The present invention provides an electrolyte composition for a lithium-ion battery comprising LiPF6 in a liquid carrier comprising a carbonate ester and an unsaturated organoboron compound comprising two or three unsaturated hydrocarbon groups, each unsaturated hydrocarbon group being covalently bonded to a boron atom. The unsaturated hydrocarbon groups are independently selected from vinyl, allyl, propargyl, substituted vinyl, substituted allyl, and substituted propargyl. The substituents of the substituted vinyl, allyl and propargyl groups independently comprise one or more of alkyl and phenyl. The alkyl and phenyl groups optionally can bear one or more substituent selected from halogen (e.g., F), hydroxy, amino, alkoxy, and perfluoroalkoxy.

Abstract: Electrolyte solutions including additives or combinations of additives that provide low temperature performance and high temperature stability in lithium ion battery cells.

Abstract: An authentication method and system includes a computing device, such as a smart phone, which includes a display for presenting a graphical and interactive game board that is used for entering a user's passcode. During the authentication process, the user selects a game board (e.g. chess, checkers, poker, backgammon, etc.) and associated game pieces for presentation on the display. The user then moves one or more game pieces to locations on the game board. Together, the selected game board, selected game pieces, and the movements and/or locations which the game pieces are moved on the game board form an entered passcode. This generated passcode is then compared with a stored passcode to authenticate the user before granting access to the computing device.

Abstract: A shoulder-surfing resistant authentication method and system includes a computing device, such as a smart phone, which includes a display for presenting an interactive virtual environment. During the authentication process, the user enters a passcode by modifying one or more attributes of one or more icons that are presented relative to the interactive environment. Such attributes may include one or more of the type of movement the icons perform, the change in position or visual characteristics of the icons relative to the virtual environment, as well as the removal and/or addition of one or more icons relative to the virtual environment. The entered passcode is then compared with a previously stored or “set” passcode to authenticate the user before granting access to the computing device.

Abstract: An authentication method and system, includes a display to present interactive three-dimensional (3D) virtual environments. The manner or sequence in which a user interacts with objects in the interactive 3D environment is used to form their passcode. The entered passcode is then compared with a previously stored or “set” passcode to determine whether the user is authenticated and permitted to access content controlled by the authentication process.

Abstract: Provided are a transmission method, terminal and system for application software. In the method, a first terminal creates a wireless hotspot; a second terminal joins a wireless network constructed by the wireless hotspot when joining request information sent by the second terminal is received; and interaction of application software with the second terminal is performed based on the wireless network. By the technical solution, the application software may be shared among these terminals, and the users do not have to download the application software from the network so as to save the data consumption of the users. Moreover, downloaded application software may also be shared among these terminals through application store clients on the terminals, so as to improve enthusiasm of the user in searching for and downloading the application software and facilitate popularization of the application store clients as well as the application software thereof.

Abstract: Electrolyte solutions including additives or combinations of additives that provide low temperature performance and high temperature stability in lithium ion battery cells.

Abstract: Described herein are additives for use in electrolytes that provide a number of desirable characteristics when implemented within batteries, such as high capacity retention during battery cycling at high temperatures. In some embodiments, a high temperature electrolyte includes a base electrolyte and one or more polymer additives, which impart these desirable performance characteristics.

Abstract: Additives to electrolytes that enable the formation of comparatively more robust SEI films on silicon anodes. The SEI films in these embodiments are seen to be more robust in part because the batteries containing these materials have higher coulombic efficiency and longer cycle life than comparable batteries without such additives.

Abstract: Electrolyte solutions including additives or combinations of additives that provide low temperature performance and high temperature stability in lithium ion battery cells.

Abstract: Electrolyte solutions including additives or combinations of additives that provide low temperature performance and high temperature stability in lithium ion battery cells.

Abstract: Described herein are additives for use in electrolytes that provide a number of desirable characteristics when implemented within batteries, such as high capacity retention during battery cycling at high temperatures. In some embodiments, a high temperature electrolyte includes a base electrolyte and one or more polymer additives, which impart these desirable performance characteristics. The polymer additives can be homopolymers or copolymers.

Abstract: An electrochemical cell including a silicon-based anode and an electrolyte, where the electrolyte is formulated to contain solvents having cyclic sulfone or cyclic sulfite chemical structure. Specific additional solvent and salt combinations yield superior performance in these electrochemical cells.

Abstract: Additives to electrolytes that enable the formation of comparatively more robust SEI films on silicon anodes. The SEI films in these embodiments are seen to be more robust in part because the batteries containing these materials have higher coulombic efficiency and longer cycle life than comparable batteries without such additives.

Abstract: Additives to electrolytes that enable the formation of comparatively more robust SEI films on silicon anodes. The SEI films in these embodiments are seen to be more robust in part because the batteries containing these materials have higher coulombic efficiency and longer cycle life than comparable batteries without such additives.

Abstract: Described herein are additives for use in electrolytes that provide a number of desirable characteristics when implemented within batteries, such as high capacity retention during battery cycling at high temperatures. In some embodiments, a high temperature electrolyte includes a base electrolyte and one or more polymer additives, which impart these desirable performance characteristics.