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Step-Growth Polymerization: Overview01:03

Step-Growth Polymerization: Overview

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Step-growth or condensation polymerization is a stepwise reaction of bi or multifunctional monomers to form long-chain polymers. As all the monomers are reactive, most of the monomers are consumed at the early stages of the reaction to form small chains of reactive oligomers, which then combine to form long polymer chains in the late stages. Hence, the reaction has to proceed for a long time to achieve high molecular weight polymers.
Many natural and synthetic polymers are produced by...
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Types of Step-Growth Polymers: Polyesters01:20

Types of Step-Growth Polymers: Polyesters

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The introduction of polyesters has brought major development to the textile industry. The wrinkle-free behavior of polyester blends has eliminated the need for starching and ironing clothes.
Polyesters are commonly prepared from terephthalic acid and ethylene glycol; the crude product is known as poly(ethylene terephthalate) or PET. However, polyesters are synthesized industrially by transesterification of dimethyl terephthalate with ethylene glycol at 150 °C. The two reactants and the polymer...
2.6K
Polymer Classification: Architecture01:14

Polymer Classification: Architecture

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Polymers are classified as linear or branched on the basis of their chain architecture. The polymer chains in linear polymers have a long chain-like structure with minimal to no branching at all. Even if a polymer features large substituent groups on the monomer, which appear as branches to the skeleton, it is not considered a branched polymer. A branched polymer contains secondary polymer chains that arise from the main polymer chain. The branching occurs when the polymer growth shifts from...
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Anionic Chain-Growth Polymerization: Overview01:20

Anionic Chain-Growth Polymerization: Overview

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The polymerization process that involves carbanion as an intermediate is called anionic polymerization. It is also a type of addition or chain-growth polymerization. Anionic polymerization gets initiated by a strong nucleophile such as an organolithium or a Grignard reagent. The most commonly used initiator for anionic polymerization is butyl lithium. Monomers involved in anionic polymerization must possess a vinyl group bonded to one or two electron-withdrawing groups. For instance,...
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Anionic Chain-Growth Polymerization: Mechanism01:04

Anionic Chain-Growth Polymerization: Mechanism

2.6K
The mechanism for anionic chain-growth polymerization involves initiation, propagation, and termination steps. In the initiation step, a nucleophilic anion, such as butyl lithium, initiates the polymerization process by attacking the π bond of the vinylic monomer. As a result, a carbanion, stabilized by the electron‐withdrawing group, is generated. The resulting carbanion acts as a Michael donor in the propagation step and attacks the second vinylic monomer, which acts as a Michael...
2.6K
Free-Radical Chain Reaction and Polymerization of Alkenes02:35

Free-Radical Chain Reaction and Polymerization of Alkenes

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The conversion of alkenes to macromolecules called polymers is a reaction of high commercial importance. The structure of the polymer is defined by a repeating unit, while the terminal groups are considered insignificant. The average degree of polymerization represents the number of repeating units in the polymer molecule and is denoted by the subscript n.
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Video Experimental Relacionado

Updated: Mar 10, 2026

Depolymerizable Olefinic Polymers Based on Fused-Ring Cyclooctene Monomers
08:12

Depolymerizable Olefinic Polymers Based on Fused-Ring Cyclooctene Monomers

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Polímeros con control autónomo del ciclo de vida

Jason F Patrick1, Maxwell J Robb1,2, Nancy R Sottos1,3

  • 1Beckman Institute for Advanced Science and Technology, University of Illinois at Urbana-Champaign, Urbana, Illinois 61801, USA.

Nature
|December 16, 2016
PubMed
Resumen
Este resumen es generado por máquina.

Los materiales inteligentes pueden imitar a los sistemas vivos para reparar los daños de forma autónoma, extendiendo la vida útil y la sostenibilidad de los artículos fabricados. El desarrollo de estos polímeros autocurativos para aplicaciones del mundo real sigue siendo un desafío significativo.

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Área de la Ciencia:

  • Ciencias de los materiales
  • Ciencia de los Polímeros
  • Biomimética

Sus antecedentes:

  • Los materiales hechos por el hombre se degradan debido al uso diario, los factores ambientales y los daños, lo que reduce la vida útil y la eliminación.
  • Los organismos vivos poseen notables capacidades para protegerse a sí mismos, reportar daños y curarse o regenerarse.
  • Imitar estas capacidades biológicas de autocuración en materiales sintéticos ofrece un camino hacia una mayor durabilidad y sostenibilidad.

Objetivo del estudio:

  • Explorar el potencial de los materiales inteligentes para extender la vida útil de los productos manufacturados.
  • Investigar enfoques para el desarrollo de materiales basados en polímeros de auto-reparación y auto-reporte.
  • Abordar los desafíos en la implementación de estas funcionalidades de materiales inteligentes en condiciones variables del mundo real.

Principales métodos:

  • Revisión de las estrategias actuales para la creación de sistemas de polímeros de auto-reparación y auto-reporte.
  • Analizar los mecanismos por los cuales los sistemas vivos logran la reparación y regeneración autónomas.
  • Identificación de las limitaciones y desafíos en la traducción de los resultados de laboratorio a aplicaciones prácticas.

Principales resultados:

  • Los materiales inteligentes ofrecen una vía prometedora para la respuesta autónoma al daño, reflejando los sistemas biológicos.
  • Se están desarrollando enfoques basados en polímeros para la autocuración, el autoinforme y las funciones regenerativas.
  • Existen obstáculos significativos para garantizar la robustez y fiabilidad de estos materiales inteligentes en entornos diversos e impredecibles.

Conclusiones:

  • Los materiales inteligentes tienen el potencial de revolucionar la longevidad, seguridad y sostenibilidad de los materiales.
  • La investigación adicional es crucial para superar los desafíos prácticos de la aplicación en el mundo real.
  • Cerrar la brecha entre el diseño biomimético y el rendimiento funcional de los materiales es clave para los avances futuros.