低表面能材料Q诸如特氟龙Q聚四氟乙烯Q涂层,以其优异的化学惰性和抗润湿性能来抵抗a(b)污的附着?/span>而这些显著的优点也得传l的胉?/span>很难与其建立理想的粘接强?/span>。随着此类低表面能材料在汽车、电(sh)子和ȝ行业的广泛应用,发展与之匚w?/span>胉?/span>变得极ؓ(f)q切。传l的解决Ҏ(gu)通过化学刻蚀、等d体和d束等处理来增加表面极性,从而削弱其表面化学惰性,以此来增?/span>_接性能。然而,实际操作中往往?/span>增加制备的复杂性和不可避免地带?/span>环境污染。因此,如何不通过表面处理可获得较强?/span>_接性能依然是工业界和学?/span>亟需解决?/span>重大N之一?/span>
鉴于此,?/span>港中文大学(深圳Q朱世^和张?/span>团队提出通过?/span>“离?span style="font-family:;">-偶极”作用引入胶黏剂设计Q赋予其对低表面能材料的高强_接Q较好地解决?jin)上q难题?/span>该研I成果以?/span>Adhering low surface energy materials without surface pre-treatment via ion-dipole interactions?/span>q期发表?/span>ACS Applied Material & Interfaces (doi: 10.1021/acsami.1c11822)Q?/span>香港中文大学Q深圻I(j)理工学院黄帅?/span>博士文第一作者,通讯作者ؓ(f)香港中文大学Q深圻I(j)理工学院׃q?/span>教授和助理教?/span>张祺博士?/span>
该课题组设计合成的胶黏剂?/span>一U?/span>?/span>含氟p物(PHFBA-co-MMAQ和疏水性离子液体(EMImTFSIQ?/span>l?/span>成的d凝胶?/span>如图1所C?/span>DFT计算l果可以发现Q基?/span>-CF3偶极?/span>EMIm阳离子的?/span>d-偶极?/span>怺作用Q胉?/span>可以与原本惰性的聚四氟乙烯表?/span>产生较强的结合能Q?/span>12.0 kcal/molQ。同时由于凝胶本?/span>材料?/span>?/span>d-偶极?/span>怺作用的动态交换,使得分离基材的力得到均匀耗散Q从而可以避免胶_剂本n׃应力集中Dq?/span>q一步?/span>q优化凝胶本w的内聚和表面粘附性能Q?/span>研究团队?/span>表面能只?/span>19 mJ/m2 的聚四氟乙烯上获?/span>1.01 MPa的胶_?/span>强度Q?/span>?/span>2Q?/span>。不仅如此,?/span>胶粘剂在不同基材Q聚丙烯?/span>聚乙?/span>?/span>聚氯乙烯?/span>ȝ?/span>陶瓷?/span>钢铁{?/span>Q表?/span>?/span>展现?/span>优异?/span>_接性能。与不同cd?/span>商业化胶黏剂Ҏ(gu)Q?/span>该胶黏剂有几倍至十几倍的性能提升Q?/span>?/span>3Q?/span>?/span>研究?/span>_接低表面能材料提供?/span>新思\Qƈ为开发可商业化的特种胉剂带来启?/span>?/span>
?/span>1.Q?/span>aQ?/span>胉剂的_?/span>接原理;Q?/span>bQ?/span>胉剂所用化学药品结构式Q(cQ?/span>EMImTFSI?/span>HFBA?/span>PTFE表面的结合能。(dQ?/span>HFBA?/span>EMImTFSI之间的内聚能?/span>
?/span>2. 通过优化EMImTFSI?/span>MMA的重量分敎ͼ获得最佳韧性和最强粘接强度的胉?/span>?/span>
?/span>3.Q?/span>aQ?/span>_接性能与离子液体的润湿性具有密切关p;Q?/span>bQ和Q?/span>cQؓ(f)d凝胶胉?/span>与商?/span>胉?/span>的性能Ҏ(gu)Q(dQ在不同基材上的宏观_接性能展示?/span>
相关链接
https://doi.org/10.1021/acsami.1c11822
