Abstract: An electronic device includes a stack structure including vertically alternating dielectric materials and conductive materials. The dielectric materials define air gaps between vertically adjacent conductive materials and include a first oxide material vertically adjacent to the conductive materials and laterally adjacent to the tunneling material, and a nitride material laterally and vertically adjacent to the first oxide material. The stack structure includes pillars extending vertically through the stack structure, the pillars including cell films adjacent to the dielectric and conductive materials. The cell films include a high-k dielectric material, a barrier oxide material, a storage node material, a tunneling material, and a channel material, wherein segments of each of the high-k dielectric material, the barrier oxide material, and the storage node material are adjacent to the conductive materials. Related methods and systems are also disclosed.

Abstract: Embodiments of this application provide a solid-state electrolyte. The solid-state electrolyte includes a porous coordination polymer having an unsaturated metal site, an anionic group coordinated with and grafted on the unsaturated metal site, and a cation bound with the anionic group. The anionic group includes one or more substituted carboxylate anionic groups and/or one or more substituted sulfonate anionic groups. The cation includes one or more of a lithium ion, a sodium ion, a potassium ion, a magnesium ion, a zinc ion, and/or an aluminum ion.

Abstract: An electronic device includes a stack structure including vertically alternating dielectric materials and conductive materials, the conductive materials including first regions and second regions, and pillars extending vertically through the stack structure, the pillars adjacent to the second regions of the conductive materials. The pillars include cell films adjacent to the second regions, the cell films including a high-k dielectric material, a barrier oxide material, a storage node material, a tunneling material, and a channel material. Segments of each of the high-k dielectric material, the barrier oxide material, and the storage node material are adjacent to the second regions. A length of the segments of high-k dielectric material and a length of the segments of storage node material adjacent to the second regions are greater than a height of the first regions of the conductive materials. Related methods and systems are also disclosed.

Abstract: This application provides a battery electrolytic solution, including an electrolyte salt and a non-aqueous organic solvent. The non-aqueous organic solvent includes a first organic solvent shown in a formula (I) and/or a second organic solvent shown in a formula (II): R1—S(?O)x—N(—R3)—R2 formula (I); and R1—S(?O)x—N(—R3)—S(?O)y—R4 formula (II). R1 and R4 are separately selected from fluoroalkyl, fluoroalkoxy, fluoroalkenyl, fluoroalkenyloxy, fluoroaryl, or fluoroaryloxy. R2 and R3 are separately selected from alkyl, alkoxy, alkenyl, alkenyloxy, aryl, or aryloxy. x is 1 or 2, and y is 1 or 2. A total content in mass of the first organic solvent and/or the second organic solvent in the electrolytic solution ranges from 10% to 90%. The electrolytic solution includes the first organic solvent and/or the second organic solvent of a high content in mass.

Abstract: A metal negative electrode and a method of making the metal negative electrode is disclosed. The metal negative electrode includes a metal negative electrode body and a protective layer formed on a surface of one side or each of two sides of the metal negative electrode body. The protective layer includes a liquid-state or gel-state inner layer that has an ability to dissolve alkali metal and a solid-state outer layer has a high ionic conductivity. The liquid-state or gel-state inner layer includes at least one of an aromatic hydrocarbon small molecule compound or a polymer containing an aromatic hydrocarbon group that each have an ability to accept an electron, and at least one of an ether small molecule solvent, an amine small molecule solvent, a thioether small molecule solvent, a polyether polymer, a polyamine polymer, or a polythioether polymer that each have an ability to complex lithium ions.

Abstract: Disclosed is a metal anode, including a metal anode body (10) and a protective layer (11) formed on one or two side surfaces of the metal anode body (10). The protective layer (11) includes a coordination polymer having an unsaturated metal site or a complexation product formed by complexation between the coordination polymer having the unsaturated metal site and anions of battery electrolyte salt. The coordination polymer uses zirconium, aluminum, or iron as a center and uses R—Xn as an organic ligand, R is n-valent hydrocarbyl, substituted hydrocarbyl, or hydrocarboxy, n is an integer in a range of 1 to 4, X is an oxygen-containing functional group capable of forming metal-oxygen chemical bond with the metal anode body (10), and the metal-oxygen chemical bond is formed between metal atoms on a surface of the metal anode body (10) and oxygen atoms in the X group.anodeanode.

Abstract: The present disclosure provides a positive electrode additive and a preparation method thereof, a positive electrode plate and a lithium-ion secondary battery. The positive electrode additive comprises a modified lithium carbonate. The modified lithium carbonate comprises a lithium carbonate particle and a polymer coating. The polymer coating coats a surface of the lithium carbonate particle and comprises a polymer. The positive electrode additive of the present disclosure has low cost and simple preparation method, when the positive electrode additive is applied in lithium-ion secondary battery, it can significantly improve lithium-ion secondary battery safety performance without affecting electrical performance of the lithium-ion secondary battery.

Abstract: The present disclosure relates to systems and methods for processing GPS information associated with a plurality of vehicles. The system may perform the methods to obtain GPS information associated with the plurality of vehicles; determine driving track information of the plurality of vehicles based on the GPS information, wherein the driving track information comprises time point information, coordinate information, and speed information of each individual vehicle in the plurality of vehicles; determine a reference point of a traffic-regulated section based on the driving track information; and determine a length of a queue for the traffic-regulated section based on the reference point and the driving track information.

Abstract: The present disclosure provides a positive electrode additive and a preparation method thereof, a positive electrode plate and a lithium-ion secondary battery. The positive electrode additive comprises a modified lithium carbonate. The modified lithium carbonate comprises a lithium carbonate particle and a polymer coating. The polymer coating coats a surface of the lithium carbonate particle and comprises a polymer. The positive electrode additive of the present disclosure has low cost and simple preparation method, when the positive electrode additive is applied in lithium-ion secondary battery, it can significantly improve lithium-ion secondary battery safety performance without affecting electrical performance of the lithium-ion secondary battery.

Abstract: The present disclosure provides a cell and a preparation method thereof. The cell comprises a positive electrode plate (1); a negative electrode plate (2) and a composite solid electrolyte membrane (3) positioned between the positive electrode plate (1) and the negative electrode plate (2). The composite solid electrolyte membrane (3) comprises inorganic solid electrolyte layers (31) and structure supporting layers (32) which are alternately laminated along a laminating direction (D), and has abutted surfaces (S1) respectively abutting against the positive electrode plate (1) and the negative electrode plate (2), an angle between the laminating direction (D) and the abutted surface (S1) is defined as ?, and 0°??<90°.

Abstract: A waterproof cap for electronic devices includes a cover plate and sealing base located on a surface of the cover plate for sealing a port of a housing of the electronic devices. A first lip and a second lip are located on an outer periphery of the sealing base and are spaced apart from each other. The first lip is located between the cover plate and the second lip. When the sealing base is inserted into the port of the housing of the electronic devices, the first lip is configured to tilt toward the cover plate, and the second lip is configured to tilt away from the cover plate.

Abstract: The present disclosure provides a cell and a preparation method thereof. The cell comprises a positive electrode plate (1); a negative electrode plate (2) and a composite solid electrolyte membrane (3) positioned between the positive electrode plate (1) and the negative electrode plate (2). The composite solid electrolyte membrane (3) comprises inorganic solid electrolyte layers (31) and structure supporting layers (32) which are alternately laminated along a laminating direction (D), and has abutted surfaces (S1) respectively abutting against the positive electrode plate (1) and the negative electrode plate (2), an angle between the laminating direction (D) and the abutted surface (S1) is defined as ?, and 0°???90°. The composite solid electrolyte membrane not only plays an advantage of a high lithium ionic conductivity of the inorganic solid electrolyte, but also has an excellent mechanical processing property, thereby significantly improving electrochemical performance and safety performance of the cell.

Abstract: A waterproof cap for electronic devices includes a cover plate and sealing base located on a surface of the cover plate for sealing a port of a housing of the electronic devices. A first lip and a second lip are located on an outer periphery of the sealing base and are spaced apart from each other. The first lip is located between the cover plate and the second lip. When the sealing base is inserted into the port of the housing of the electronic devices, the first lip is configured to tilt toward the cover plate, and the second lip is configured to tilt away from the cover plate.

Abstract: The present invention belongs to the technical field of lithium ion batteries and in particularly relates to a composite anode material for a lithium ion battery. The composite anode material for a lithium ion battery comprises an anode active material and a coating layer coating the surface of the anode active material, wherein the anode active material is at least one selected from the group of Si, SiOx or a silicon alloy, the coating layer, which is a polymer of a network structure, accounts for 1-20% by mass of the anode material.

Abstract: A nanostructure and methods of synthesizing same. In one embodiment, the nanostructure includes a nanospecies, a hydrophobic protection structure including at least one compound selected from a capping ligand, an amphiphilic copolymer, and combinations thereof, wherein the hydrophobic protection structure encapsulates the nanospecies, and at least one histidine-tagged peptide or protein conjugated to the hydrophobic protection structure, wherein the at least one histidine-tagged peptide or protein has at least one binding site.

Abstract: An ultra wideband antenna (20) is disposed on a substrate (10). The substrate includes a first surface (101) and a second surface (102). The ultra wideband antenna includes a radiation body (22), a feeding portion (26), and a grounded portion (28). The radiation body disposed on the first surface is used for transceiving electromagnetic signals. The radiation body includes a semicircle-shaped metal portion (222) and a rectangle-shaped metal portion (224) and defines a slot (24) starting at an edge therein. The feeding portion is electronically connected to the radiation body for feeding signals to the radiation body. The grounded portion is disposed on the second surface.

Abstract: A MIMO antenna is disposed on a substrate. The substrate includes a first surface and a second surface. The MIMO antenna includes a first antenna and a second antenna set as mirror image to the first antenna, each of the first and the second antennas includes a radiation body, a feeding portion, and a grounded portion. The radiation portion is disposed on the first surface for transceiving electromagnetic signals. The radiation body includes a first radiation portion and a second radiation portion electronically connected to the first radiation portion. The first radiation portion is serpentine-shaped and the second radiation portion is rectangular-shaped. The feeding portion is disposed on the first surface, and electronically connected to the second radiation portion for feeding electromagnetic signals to the radiation body. The grounded portion is disposed on the second surface.

Abstract: A dual-band antenna (10) is disposed on a substrate (200). The substrate includes a first surface (210) and a second surface (220). The dual antenna includes a feeding portion (110), a first radiation portion (120), a second radiation portion (130), a first grounded portion (140) , a second grounded portion (150), and a connecting portion (160). The feeding portion is disposed on the first surface, for feeding electromagnetic signals. The first radiation portion, disposed on the first surface, is electronically connected to the feeding portion. The second radiation portion, disposed on the second surface, is electronically connected to the feeding portion. The first grounded portion is disposed on one side of the feeding portion. The second grounded portion is disposed on the other side of the feeding portion. The connecting portion is for electronically connecting the first radiation portion, the second radiation portion, and the feeding portion.

Abstract: A nanostructure and methods of synthesizing same. In one embodiment, the nanostructure includes a nanospecies, a hydrophobic protection structure including at least one compound selected from a capping ligand, an amphiphilic copolymer, and combinations thereof, wherein the hydrophobic protection structure encapsulates the nanospecies, and at least one histidine-tagged peptide or protein conjugated to the hydrophobic protection structure, wherein the at least one histidine-tagged peptide or protein has at least one binding site.

Abstract: A MIMO antenna is disposed on a substrate. The substrate includes a first surface and a second surface. The MIMO antenna includes a first antenna and a second antenna set as mirror image to the first antenna, each of the first and the second antennas includes a radiation body, a feeding portion, and a grounded portion. The radiation portion is disposed on the first surface for transceiving electromagnetic signals. The radiation body includes a first radiation portion and a second radiation portion electronically connected to the first radiation portion. The first radiation portion is serpentine-shaped and the second radiation portion is rectangular-shaped. The feeding portion is disposed on the first surface, and electronically connected to the second radiation portion for feeding electromagnetic signals to the radiation body. The grounded portion is disposed on the second surface.