An electrode for a battery cell, including an active material which contains silicon and which contains a first polymer which is ionically conductive. The active material contains in this case a copolymer, which includes the first polymer and a second polymer, the second polymer being electrically conductive. The A battery cell which includes at least one electrode is also described.

An electrode for an electrochemical element with an organic electrolyte includes a polymeric material containing or composed of subunits according to general formulae (I) and/or (II):

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wherein n is an integer >2, Y represents an amide group (—NH—CO— or —CO—NH—), an ester group (—O—CO— or —CO—O—) or a urethane group (—NH—CO—O— or —O—CO—NH—), R.sub.1, R.sub.2, R.sub.3 and R.sub.4 each independently represent H, alkyl (preferably —CH.sub.3, —C.sub.2H.sub.5), Alkoxy-(preferably —OCH.sub.3, —OC.sub.2H.sub.5), -halogen or —CN, Ar.sub.1 and Ar.sub.4 independently represent a bridging aryl group, Ar.sub.e and Ar.sub.a independently represent a non-bridging aryl group, and R.sub.5 is a bridging alkyl, alkene or aryl group, wherein Ar.sub.1 and Ar.sub.4 in structures (I) and (II) independently represent a bridging aryl group.

A process can be used to produce a charge storage unit, especially a secondary battery, the electrodes of which contain an organic redox-active polymer, and which includes a polymeric solid electrolyte. The solid electrolyte is obtained by polymerizing from mixtures of acrylates with methacrylates in the presence of at least one ionic liquid, which imparts advantageous properties to the charge storage unit.

A sodium ion secondary battery includes a cyclic organic compound as an active material and a complex hydride as a solid electrolyte, wherein the cyclic organic compound has at least two carbonyl groups —C(═O)—, the at least two carbonyl groups are bonded via a single bond or at least one conjugated double bond, and the complex hydride includes a Na cation and a complex ion containing H.

An electrode for an electrochemical energy storage device having interlayers of vanadium oxygen hydrate (VOH); and polyaniline (PANI) intercalated in the interlayers of VOH. A method for making the same and an electrochemical energy storage device including the aforementioned electrode are also discussed herein.

There is provided a positive electrode material for a lithium-sulfur battery, including a sulfur-rich polymer and graphene, wherein an internal structure of the sulfur-rich polymer is an interpenetrating network structure; the graphene is doped in the sulfur-rich polymer; a particle size of the sulfur-rich polymer is 100-300 meshes; and the number of flake layers of the graphene is 2-10. A preparation method includes: crushing a prepared sulfur-rich polymer into powder, adding a solvent to obtain a solution, performing sufficient stirring processing; performing ultrasonic dispersion on graphene in a solvent to generate a suspension; and mixing the two solutions, then continuing to perform ultrasonic dispersion and stirring, and finally removing the solvent and drying a product to obtain the positive electrode material for a lithium-sulfur battery. The positive electrode material for a lithium-sulfur battery has relatively high conductivity and cycle performance and a long service life, and is simple to operate.

An electricity storage device includes a positive electrode containing a positive electrode active material, a negative electrode containing a negative electrode active material, and an electrolyte that includes an organic crystal layer including a layered structure and an organic solvent introduced into the organic crystal layer and that is interposed between the positive electrode and the negative electrode to conduct alkali metal ions. The layered structure includes an organic backbone layer containing an aromatic dicarboxylic acid anion having an aromatic ring structure, and an alkali metal element layer containing an alkali metal element that is coordinated with oxygen contained in a carboxylic acid of the organic backbone layer to form a framework. At least one of the positive electrode and the negative electrode adsorbs and desorbs the ions to store and release electric charge.

A method for manufacturing an electrochemical device includes the following steps: a step of preparing a positive electrode, the positive electrode including a first current collector and a positive electrode layer containing a conductive polymer; a step of preparing a negative electrode, the negative electrode including a second current collector and a negative electrode layer; and a step of sealing the positive electrode, the negative electrode, and an electrolytic solution in an exterior body. The step of preparing the positive electrode includes a step of holding the positive electrode in depressurized atmosphere and then introducing gas containing CO.sub.2 as a primary component into the depressurized atmosphere.

A battery cell formed of anode made from an n-type polymer and a cathode made from a p-type polymer with an electrolyte between the anode and the cathode. The anode and cathode are formed by depositing a compound that contains a non-volatile electrolyte that creates pathways in the deposited anode and the cathode. The n-type polymer and the p-type polymer are polymers that include a repeat unit of the following formula:

Crosslinked polymers and related compositions and related compositions, electrochemical cells, batteries, methods and systems are described. The crosslinked polymers have at least one redox active monomeric moiety having a redox potential of 0.5 V to 3.0 V with reference to Li/Li.sup.+ electrode potential under standard conditions or −2.54 V to −0.04 V vs. SHE and has a carbocyclic structure and at least one carbonyl group or a carboxyl group on the carbocyclic structure. The crosslinked polymers also include at least one comonomeric moiety with at least one of the at least one redox active monomeric moiety and/or the at least one comonomeric moiety has a denticity of three to six corresponding to a three to six connected network polymer, and provide stable, high capacity organic electrode materials.