Chen Changhao, Tian Ze, Luo Xiao, Jiang Guochen, Hu Xinyu, Wang Lizhong, Peng Rui, Zhang Hongjun, Zhong Minlin
Laser Materials Processing Research Center, Key Laboratory for Advanced Materials Processing Technology (Ministry of Education), School of Materials Science and Engineering, Tsinghua University, Beijing 100084, P. R. China.
Tsinghua University(SMSE) - AVIC - ARI Joint Research Center for Advanced Materials and Anti-Icing, Tsinghua University, Beijing 100084, P. R. China.
ACS Appl Mater Interfaces. 2022 May 25;14(20):23973-23982. doi: 10.1021/acsami.2c02992. Epub 2022 May 10.
Anti-icing superhydrophobic surfaces have attracted tremendous interests due to their repellency to water and extremely low ice affinity, whereas the weak durability has been the bottleneck for further applications. Surface durability is especially important in long-term exposure to low-temperature and high-humidity environments. In this study, a robust micro-nano-nanowire triple structure-held PDMS superhydrophobic surface was fabricated via a hybrid process: ultrafast-laser-prepared periodic copper microstructures were chemically oxidized, followed by modification of PDMS. The hedgehog-like surface structure was composed of microcones, densely grown nanowires, and tightly combined PDMS. The capillary force difference in micro-nanostructures drove PDMS solutions to distribute evenly, bonding fragile nanowires to form stronger composite cones. PDMS replaced the commonly used fragile fluorosilanes and protected nanowires from breaking, which endowed the surfaces with higher robustness. The ductile PDMS-nanowire composites possessed higher resiliency than brittle nanowires under a load of 1 mN. The surface kept superhydrophobic and ice-resistant after 15 linear abrasion cycles under 1.2 kPa or 60 icing-deicing cycles under -20 °C or 500 tape peeling cycles. Under a higher pressure of 6.2 kPa, the contact angle (CA) was maintained above 150° until the abrasion distance exceeded 8 m. In addition, the surface exhibited a rare spontaneously optimized performance in the icing-deicing cycles. The ice adhesion strength of the surface reached its lowest value of 12.2 kPa in the 16th cycle. Evolution of surface roughness and morphology were combined to explain its unique U-shaped performance curves, which distinguished its unique degradation process from common surfaces. Thus, this triple-scale superhydrophobic surface showed a long-term anti-icing performance with high deicing robustness and low ice adhesion strength. The proposed nanostructure-facilitated uniform distribution strategy of PDMS is promising in future design of durable superhydrophobic anti-icing surfaces.
防冰超疏水表面因其对水的排斥性和极低的冰亲和性而引起了极大的关注,然而其耐久性较弱一直是进一步应用的瓶颈。表面耐久性在长期暴露于低温高湿环境中尤为重要。在本研究中,通过一种混合工艺制备了一种坚固的微纳-纳米线三重结构支撑的聚二甲基硅氧烷(PDMS)超疏水表面:超快激光制备的周期性铜微结构经过化学氧化,然后进行PDMS改性。刺猬状表面结构由微锥、密集生长的纳米线和紧密结合的PDMS组成。微纳结构中的毛细力差驱使PDMS溶液均匀分布,将脆弱的纳米线粘结形成更强的复合锥体。PDMS取代了常用的脆弱氟硅烷,并保护纳米线不被折断,从而赋予表面更高的坚固性。在1 mN的负载下,韧性的PDMS-纳米线复合材料比脆性纳米线具有更高的弹性。在1.2 kPa下经过15次线性磨损循环、在-20℃下经过60次结冰-融冰循环或500次胶带剥离循环后,表面仍保持超疏水和抗冰性能。在6.2 kPa的更高压力下,接触角(CA)保持在150°以上,直到磨损距离超过8 m。此外,该表面在结冰-融冰循环中表现出罕见的自发优化性能。在第16个循环中,表面的冰粘附强度达到最低值12.2 kPa。结合表面粗糙度和形貌的演变来解释其独特的U形性能曲线,这使其独特的降解过程与普通表面区分开来。因此,这种三重尺度超疏水表面表现出长期的防冰性能,具有高融冰坚固性和低冰粘附强度。所提出的纳米结构促进PDMS均匀分布的策略在未来耐用超疏水防冰表面的设计中具有广阔前景。
