Abstract: An anode and a lithium ion battery employing the same are provided. The anode includes a lithium-containing layer and a single-ion conductive layer. The single-ion conductive layer includes an inorganic particle, a single-ion conductor polymer, and a binder. The single-ion conductor polymer has a first repeat unit of Formula (I), a second repeat unit of Formula (II), a third repeat unit of Formula (III), and a fourth repeat unit of Formula (IV) wherein R1 is O?M+, SO3?M+, N(SO2F)?M+, N(SO2CF3)?M+, N(SO2CF2CF3)?M+, COO?M+, or PO4?M+; M+ is Li+, Na+, K+, Cs+, or a combination thereof; and R2 is CH3, CH2CH3, or CH2CH2OCH2CH3. In particular, the weight ratio of the inorganic particle to the sum of the single-ion conductor polymer and the binder is from 4:1 to 9:1, and the weight ratio of the binder to the single-ion conductor polymer is from 1:1 to 9:1.

Abstract: An anode and a lithium ion battery employing the same are provided. The anode includes a lithium-containing layer and a single-ion conductive layer. The single-ion conductive layer includes an inorganic particle, a single-ion conductor polymer, and a binder. The single-ion conductor polymer has a first repeat unit of Formula (I), a second repeat unit of Formula (II), a third repeat unit of Formula (III), and a fourth repeat unit of Formula (IV) wherein R1 is O?M+, SO3?M?, N(SO2F)?M+, N(SO2CF3)?M+, N(SO2CF2CF3)?M+, COO?M+, or PO4?M+; M+ is Li+, Na+, K+, Cs+, or a combination thereof; and R2 is CH3, CH2CH3, or CH2CH2OCH2CH3. In particular, the weight ratio of the inorganic particle to the sum of the single-ion conductor polymer and the binder is from 4:1 to 9:1, and the weight ratio of the binder to the single-ion conductor polymer is from 1:1 to 9:1.

Abstract: A polyelectrolyte includes a first segment and a second segment, wherein the structure of the first segment is at least one of formula (1) and formula (2); the structure of the second segment is at least one of formula (3) and formula (4). The polyelectrolyte undergoes microphase separation to form a nanoscale ordered self-assembled microstructure.

Abstract: A polyelectrolyte includes a first segment and a second segment, wherein the structure of the first segment is at least one of formula (1) and formula (2); the structure of the second segment is at least one of formula (3) and formula (4). The polyelectrolyte undergoes microphase separation to form a nanoscale ordered self-assembled microstructure.

Abstract: A solid memory module with extensible capacity includes at least a non-volatile memory module, each of which has at least a memory chip and a first connector, and at least a second connector, which electrically connects the first connector of the volatile memory module, at least a control unit and as a system interface. This control unit obtains external signals by this system interface and then transmits to this non-volatile memory module by the control unit to store or use the memory content.

Abstract: A non-volatile memory module package capability of replacing, it may connected to a solid memory module, which includes a control unit, a system interface, and a first connector, the control unit may obtains external signals by the system interface, and then transmitted to this non-volatile memory module by the control unit to store or use the memory content. The package includes a substrate; a second connector is arranged on the substrate for inserting the first connector of the solid memory module; at least a non-volatile memory chip located on the substrate, and electrically connected the substrate and the second connector; at least a passive component is arranged on the substrate; and a compound resin is covered on the non-volatile memory chip and passive component.

Abstract: A solid memory module structure with extensible capacity includes at least a non-volatile memory module, each of which has at least a memory chip, a first connector, and a control unit. And A Solid memory module includes at least a second connector, which electrically connects the first connector of the volatile memory module, and a system interfac3. The control unit of the non-volatile memory module obtains external signals by this system interface and then transmits to this non-volatile memory module by the control unit to store or use the memory content.