ISSN   1004-0595

CN  62-1224/O4

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基于主客体相互作用的水下自适应仿生胶黏剂的设计及性能研究

Self-assembled Bioinspired Underwater Adhesive by Host-guest Interaction

  • 摘要: 水下胶黏剂在多个领域中有着巨大的应用潜力,以往报道的胶黏剂大都需要外界能量的触发实现水下固化,这很大程度上限制了其应用范围. 因此,亟需开发1种能在水下自适应黏附的胶黏剂来扩展其应用的灵活性和实用性. 为此,本文中报道了1种以水为触发开关,通过金刚烷和β-环糊精的主客体作用在水下自适应组装形成稳定的包合物来提升内聚能,实现高强度水下黏附. 这种合理的设计使胶黏剂可以在多种水环境(超纯水、酸和碱溶液、海水)中直接作业,并对多种基材表现出具有良好的润湿性和强大的黏合效果(纯水中黄铜基材上浸泡12 h后黏附强度达940.8 kPa),且随时间延长黏附强度没有降低(15天后仍保持高强度),同时表现出了杰出的可循环使用性(10次循环仍稳定),将有助于减轻对海洋生态系统和环境的负担. 这种原位水下自适应固化策略极大地提高了其在复杂环境下的应用便利性,将丰富新兴的水下胶黏剂领域.

     

    Abstract: Designing and developing adhesives that bond strongly to wet surfaces in humid environments or completely submerged in water has been a real challenge. Curing of underwater adhesives usually requires a long time as well as external energy, which limits the range of applications for underwater adhesives. We overcame these problems by integrating the host-guest interactions of adamantane (AD) and β-Cyclodextrin (β-CD) and the hydrophobic interactions of polydimethylsiloxane (PDMS) into a single system and mimicking the adhesion mechanism of mussel foot proteins. We prepared hyperbranched polymers P1 containing adhesion groups dihydroxyphenylalanine (DOPA) and AD, as well as PDMS polymers P2 capped with β-CD. Through a one-step Michael addition reaction, the adhesion functional group DOPA, the rigid hydrophobic group benzylamine hydrochloride (BENA), and the guest functional unit AD were successfully integrated into the hyperbranched polymers P1. The (β-CD)-capped PDMS host polymers P2 was obtained by reacting the host functional unit β-CD with poly(dimethylsiloxane), diglycidyl ether terminated (PDMS-DGE). The host-guest underwater adhesive was obtained by mixing P1 and P2 polymer solutions and forming a stable inclusion P3 complex of AD with β-CD in water. Strong underwater adhesion was mainly realized through three points: 1. AD and β-CD were adaptively underwater assembled through the host-guest interaction, which squeezed out the water from the inner cavity of the β-CD, realizing the hydrophobic repulsion of molecular chains and increasing the cohesive energy; 2. the catechol group of DOPA formed a large number of hydrogen bonds with the surface of the substrate, resulting in strong interfacial adhesion; 3. hydrophobic PDMS resisted water erosion and protected the internal polymer chain, thus achieving the strength of the underwater adhesion stable for a long period of time. Experimental tests had shown that this rational design endowed the underwater adhesive with exceptional performance. The stabilized inclusion P3 formed through adaptive assembly exhibited strong underwater adhesion strength (brass substrate in pure water 12 h reaches 940.8kPa), which was a significant improvement over the adhesion strength of existing underwater adhesives (200~600 kPa). Significantly, P3 required only one hours to initially cure and adhere the substrate tightly, and reached peak adhesion strength after 12h of curing. Contact angle tests had confirmed the good wettability of P3 adhesives on different substrate surfaces (organic and inorganic). This allowed the adhesive to tend to displace interfacial water when applied to the substrate in an underwater environment, thereby gaining sufficient contact area on the substrate to achieve strong adhesion to a wide range of substrates. In addition to its strong adhesive properties, our underwater adhesive remained stable in a wide range of aquatic environments (ultrapure water, acidic and alkaline solutions, seawater). Even after 15 days of immersion in water, it maintained high adhesion strength. The host-guest adhesive P3 maintained strong adhesion properties after several adhesion-detachment cycles underwater, which proved its reusability. Economically and environmentally, this not only helped to reduce costs, but was also in line with the concept of green chemistry, which protected the environment and helped to reduce the burden on marine. This in-situ underwater adaptive curing strategy greatly improved the ease of application of underwater adhesives in complex environments and provides abundant possibilities for the subsequent design of a new generation of green underwater adhesives that combined high adhesion strength, long-term durability and stability in harsh environments.

     

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