笼形水合物和石蜡粘附是造成油气输送管线堵塞的重要原因，本项目以抑制笼形水合物和 石蜡在固体表面的粘附为目标，基于表面的粘附现象的认识以及分子设计的理念，仿生构筑具有 猪笼草结构的超光滑抗沾污表面。采用氟硅烷偶联剂、甲基三甲氧基硅烷、纳米硅溶胶等为原 料，利用溶胶-凝胶法水解共缩合制备具有纳微多尺度结构的含氟杂化涂层，再以此为基材， 浸润端基反应型全氟油，构建全疏型抗粘附的超光滑表面。系统研究该表面的抗粘附与防覆冰 性能，探讨超光滑表面的形成与超润滑机理，考察在强化破坏与损失环境下的超浸润表面的耐 久性。进一步以自制环戊烷与水形成的笼形水合物为模型，定量分析水合物以及结晶蜡在超光 滑表面上的粘附作用，从科学上揭示超润滑表面的形成与粘附机制，为新型抗水合物与石蜡粘 附材料的开发提供新的思路和理论依据。

The adhesion of clathrate hydrate and paraffin is main cause for pipeline blocking of oil and gas transmission. The purpose of this project is to prohibit the adhesion of clathrate hydrate and paraffin on the solid surface. Based on the scientific cognition about the adhesion mechanism of fouling agent and solid surface, combined with the molecular design concept, the biomimetic super slippery coating material with low surface free energy will be constructed. The constructing mechanism of the novel biomimetic super slippery coating material, the theories of stabilization, and the special surface physical and chemical properties will be explored systematically. Setting fluorosilane coupling agent, methyltrimethoxysilane (MTMS) and nano silicon sol will be supplied as raw materials, the fluorinated hybridization coating comprised of micro-nano hierarchical structure will be prepared via sol-gel method through hydrolytic condensation. Subsequently, the hierarchical fluorinated hybridization coating will be infused with various kinds of reactive fluorosilicone oil with low surface energy. Finally, the Nepenthes mirabilis-inspired omniphobic anti-adhesive super slippery surface will be acquired. The omniphobic, anti-adhesive and anti-icing properties will be investigated, and the mechanisms of the formation of the super slippery surface will be explored. In addition, the long-term stability of the super slippery surface under extremely strict conditions will also be tested. Furthermore, the homemade clathrate hydrate which is consisted of cyclopentane and water will be modelled to quantitatively analysis the adhesive effect of clathrate hydrate and crystalline wax on the super slippery surface. The regime of the formation of the super slippery surface and the adhesion property will be revealed from the scientific aspect. The design, preparation, and systematically investigation of the biomimetic super slippery antifouling coating endowed with low surface energy will provide new idea and theoretical evidence for the development of new anti-adhesive materials aimed at clathrate hydrate and paraffin.