The present disclosure provides, in some aspects, macromonomers of Formula (I), and salts thereof; methods of preparing the macromonomers, and salts thereof; Brush prodrugs (polymers); methods of preparing the Brush prodrugs; compounds of Formula (II); conjugates of Formula (III), and salts thereof; pharmaceutical compositions comprising a Brush prodrug, or a conjugate or a salt thereof; kits comprising: a macromonomer or a salt thereof, a Brush prodrug, a compound, a conjugate or a salt thereof, or a pharmaceutical composition; methods of using the Brush prodrugs, or conjugates or salts thereof; and uses of the Brush prodrugs, and conjugates or salts thereof. These chemical entities may be useful in delivering pharmaceutical agents to a subject or cell. ##STR00001##

The present disclosure relates to a carbazole-based anion exchange material, a preparation method therefor and use thereof, and more particularly, to an anion exchange material used in membranes for water electrolysis, redox flow batteries, fuel cells, carbon dioxide reduction, electrochemical ammonia production and decomposition, electrodialysis (ED), reverse electrodialysis (RED) or capacitive deionization (CDI), a separator comprising the same, a preparation method therefor and use thereof. According to the present disclosure, it is possible to prepare a separation membrane with improved mechanical and chemical stability and durability by remarkably improving the molecular weight together with solubility in solvent by providing the anion exchange material in which all bonds between monomers in the main chain are CC bonds based on the carbazole-based material with high stability.

The present invention relates to the field of cationic polymers, and in particular, to highly alkali-stable poly(arylene alkylene piperidinium) cationic polymers and preparation methods and applications. The preparation method for the highly alkali-stable poly(arylene alkylene piperidinium) cationic polymers includes the following steps: performing catalytic polycondensation on 1-R.sup.6-piperidine-3-carboxaldehyde or a salt or hydrate thereof and an aromatic compound to obtain a polymer having a piperidine moiety; and then further subjecting the polymer to a quaternization reaction to obtain the poly(arylene alkylene piperidinium) cationic polymer. The anion exchange membranes prepared from the piperidinium-based cationic polymers have ultra-high alkaline stability and excellent mechanical properties and ionic conductivities, and can be applied to the fields of electrochemical energy conversion such as fuel cells, hydrogen production by water electrolysis, electrochemical reduction of carbon dioxide, flow batteries, and fields of separation such as electrodialysis and water treatment.

The present disclosure relates to the field of cationic polymers, and in particular to highly alkali-stable poly(arylene alkylene piperidinium) cationic polymers having branched structures, and the preparation method and application thereof. The highly alkali-stable poly(arylene alkylene piperidinium) cationic polymers having branched structures include one or more of a central unit, a linear unit L.sub.1, and a linear unit L.sub.2, where the central unit includes one or more of an MA unit, a piperidinium group (m-DMP) and a CA unit, the linear unit L.sub.1 includes the piperidinium group (m-DMP) and a BA unit, and the linear unit L.sub.2 includes a BA unit and a CA unit. The disclosure employs the aforementioned steps to enhance the intermolecular interactions and increase the molecular weight of the polymer through a branching strategy.

A solid electrolytic capacitor containing a capacitor element is provided. The capacitor element contains a sintered porous anode body, a dielectric that overlies the anode body, and a solid electrolyte that overlies the dielectric. An anode lead extends from the front surface of the capacitor element in the longitudinal direction. An anode termination is in contact with the anode lead at a connection region, wherein the ratio of the distance between the connection region and the front surface of the capacitor element to the length of the capacitor is 0.13 or more. A cathode termination is in electrical connection with the solid electrolyte and a casing material encapsulates the capacitor element and anode lead. Further, an interfacial coating that is disposed on at least a portion of the anode termination and/or cathode termination and is in contact with the casing material.

The present disclosure relates to a polymer for a photolithographic medium composition, and the photolithographic medium composition. The polymer has a structural unit represented by general formula (1) below. The polymer of the present disclosure maintains a carbon-rich structure (i.e., a polybenzene ring structure) while a sec-hydroxyl structure is introduced into the structure. The sec-hydroxyl structure can provide cross-linking sites during the film formation process of the material, which can improve the overall cross-linking density of the material, and consequently improve the etching resistance of the material. In addition, the sec-hydroxyl structure can serve as polar interaction sites, and has a strong movement ability, contributing to the improvement of the ability to interact with solvents. Thus, the solubility performance of the material is improved. The polymer of the present disclosure has excellent performance in the solubility and etching resistance, and the solubility of the polymer is improved while the etching resistance is considered. Thus, the polymer is very suitable as the material for an etching-resistant medium layer.

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