材料科学                        
                
                                
                        
                            冷凝                        
                
                                
                        
                            跳跃的                        
                
                                
                        
                            纳米技术                        
                
                                
                        
                            化学工程                        
                
                                
                        
                            接口(物质)                        
                
                                
                        
                            胶粘剂                        
                
                                
                        
                            复合材料                        
                
                                
                        
                            润湿                        
                
                                
                        
                            图层(电子)                        
                
                                
                        
                            坐滴法                        
                
                                
                        
                            生物                        
                
                                
                        
                            物理                        
                
                                
                        
                            生理学                        
                
                                
                        
                            工程类                        
                
                                
                        
                            热力学                        
                
                        
                    
            作者
            
                Jingcheng Ma,Zhuoyuan Zheng,Muhammad Jahidul Hoque,Longnan Li,Kazi Fazle Rabbi,Jin Yao Ho,Paul V. Braun,Pingfeng Wang,Nenad Miljkovic            
         
                    
            出处
            
                                    期刊:ACS Nano
                                                         [American Chemical Society]
                                                        日期:2022-03-11
                                                        卷期号:16 (3): 4251-4262
                                                        被引量:35
                                 
         
        
    
            
            标识
            
                                    DOI:10.1021/acsnano.1c10250
                                    
                                
                                 
         
        
                
            摘要
            
            Creating thin (<100 nm) hydrophobic coatings that are durable in wet conditions remains challenging. Although the dropwise condensation of steam on thin hydrophobic coatings can enhance condensation heat transfer by 1000%, these coatings easily delaminate. Designing interfaces with high adhesion while maintaining a nanoscale coating thickness is key to overcoming this challenge. In nature, cell membranes face this same challenge where nanometer-thick lipid bilayers achieve high adhesion in wet environments to maintain integrity. Nature ensures this adhesion by forming a lipid interface having two nonpolar surfaces, demonstrating high physicochemical resistance to biofluids attempting to open the interface. Here, developing an artificial lipid-like interface that utilizes fluorine-carbon molecular chains can achieve durable nanometric hydrophobic coatings. The application of our approach to create a superhydrophobic material shows high stability during jumping-droplet-enhanced condensation as quantified from a continual one-year steam condensation experiment. The jumping-droplet condensation enhanced condensation heat transfer coefficient up to 400% on tube samples when compared to filmwise condensation on bare copper. Our bioinspired materials design principle can be followed to develop many durable hydrophobic surfaces using alternate substrate-coating pairs, providing stable hydrophobicity or superhydrophobicity to a plethora of applications.
         
            
 
                 
                
                    
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