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Polymer Classification: Architecture01:14

Polymer Classification: Architecture

2.9K
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...
2.9K
Anionic Chain-Growth Polymerization: Overview01:20

Anionic Chain-Growth Polymerization: Overview

1.8K
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,...
1.8K
Cationic Chain-Growth Polymerization: Mechanism00:57

Cationic Chain-Growth Polymerization: Mechanism

2.1K
The cationic polymerization mechanism consists of three steps: initiation, propagation, and termination. In the initiation step of the polymerization process, the π bond of a monomer gets protonated by the Lewis acid catalyst, which is formed from boron trifluoride and water. The protonation of the π bond generates a carbocation stabilized by the electron‐donating group. In the propagation step, the π bond of the second monomer acts as a nucleophile and attacks the...
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Types of Step-Growth Polymers: Polyesters01:20

Types of Step-Growth Polymers: Polyesters

1.7K
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...
1.7K
Bioplastics01:27

Bioplastics

73
Bioplastics derived from microbial processes present a sustainable alternative to conventional petroleum-based plastics. Among these, polyhydroxyalkanoates (PHAs), particularly polyhydroxybutyrates (PHBs), have emerged as prominent candidates due to their biodegradability and biocompatibility. These polymers are synthesized by a variety of bacteria, such as Cupriavidus necator and Pseudomonas putida, which naturally accumulate PHAs as intracellular carbon and energy reserves, especially under...
73
Microbial Bioremediation of Plastics01:28

Microbial Bioremediation of Plastics

142
Polyethylene terephthalate (PET) is a synthetic polymer widely utilized in the packaging industry, particularly for bottles and containers. Due to its chemical stability and durability, PET accumulates in the environment, contributing significantly to plastic pollution. It comprises repeating units of terephthalic acid and ethylene glycol, resulting in a semi-crystalline structure that is resistant to natural degradation processes.A notable breakthrough in plastic biodegradation came with the...
142

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Updated: May 5, 2026

Solid-state Graft Copolymer Electrolytes for Lithium Battery Applications
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Solid-state Graft Copolymer Electrolytes for Lithium Battery Applications

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効率的な有機高出力エネルギー貯蔵のためのバイオベースのポリ (ヒドロキシウレタン)

Florian Le Goupil1, Victor Salvado1, Valère Rothan1

  • 1Laboratoire de Chimie des Polymères Organiques (LCPO UMR 5629), Université de Bordeaux, CNRS, 16 Avenue Pey-Berland, Bordeaux INP, 33607 Pessac Cedex, France.

Journal of the American Chemical Society
|February 17, 2023
PubMed
まとめ

完全にバイオベースのポリ・ヒドロキシウレタンは エネルギー貯蔵のための持続可能な解決策を提供します. これらの材料は石油化学の代替品に匹敵する高いエネルギー密度と効率を備えており,よりグリーンな技術への道を切り開いています.

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Morphology Control for Fully Printable Organic–Inorganic Bulk-heterojunction Solar Cells Based on a Ti-alkoxide and Semiconducting Polymer
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Synthesis of Soft Polysiloxane-urea Elastomers for Intraocular Lens Application
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Synthesis of Soft Polysiloxane-urea Elastomers for Intraocular Lens Application

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関連する実験動画

Last Updated: May 5, 2026

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Morphology Control for Fully Printable Organic–Inorganic Bulk-heterojunction Solar Cells Based on a Ti-alkoxide and Semiconducting Polymer
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Synthesis of Soft Polysiloxane-urea Elastomers for Intraocular Lens Application
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Synthesis of Soft Polysiloxane-urea Elastomers for Intraocular Lens Application

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科学分野:

  • 材料科学
  • エネルギー貯蔵
  • ポリマー化学

背景:

  • 持続可能なエネルギー源は 断続性を管理するために 効率的なエネルギー貯蔵を必要とします
  • オーガニックポリマーは,高電力コンデンサのスケーラブルで緑の介電体として調査されています.
  • 既存の材料はしばしば石油化学源に依存し,バイオベースの代替材料の必要性を強調しています.

研究 の 目的:

  • 高性能エネルギー貯蔵用の完全バイオベースのポリヒドロキシウレタン (PHU) を合成し,特徴づけること.
  • 合成されたPHUの放電性および分解強度を含む介電特性評価.
  • バイオベースのPHUのエネルギー貯蔵性能と効率を評価する.

主な方法:

  • エリトロール二酸化炭素とバイオベースのダイアミンを反応させ,バイオベースのPHUを合成する.
  • PHUの特性:ガラスの移行温度 (Tg),許容性 (εr),分解強度 (EB),および介電損失 (tan δ).
  • 放電エネルギー密度 (Ue) と放電効率 (η) を含むエネルギー貯蔵性能の評価

主要な成果:

  • 完全にバイオベースのPHUを合成し,ガラス化温度 (Tg) は約50°Cです.
  • 高許容性 (εr > 8) と破裂強度 (EB > 400 MV·m−1) を達成した.
  • 証明された低介電損失 (tan δ < 0.03) と高い放電エネルギー密度 (Ue > 6 J·cm−3).
  • 放電効率が優れている (η = EBで85%,0.5 EBで91%まで).

結論:

  • バイオベースのPHUは,高出力コンデンサのアプリケーションに有望な介電性を持っています.
  • 合成されたPHUは,石油化学ベースの材料に匹敵するエネルギー貯蔵性能を提供します.
  • これらのバイオベースの材料は,グリーンエネルギー貯蔵ソリューションの持続可能で効率的な経路を表しています.