Bioinspired Design of a Superoleophobic and Low Adhesive Water/Solid Interface†

Oil/water separation is an important field, not only for scientific research but also for practical applications aiming to resolve industrial oily wastewater and oil-spill pollution, as well as environmental protection. Recently, research into the role of special wettability for oil/water separation has attracted much attention. In this review we summarize the design, fabrication, applications and recent developments of special wettable materials for oil/water separation. Based on the different types of separation, we organize this review into three parts: “oil-removing” type materials with superhydrophobicity and superoleophilicity (that selectively filter or absorb oil from oil/water mixtures), “water-removing” type materials with superhydrophilicity and superoleophobicity (that selectively separate water from oil/water mixtures), and smart controllable separation materials. In each section, we present in detail the representative work, introduce the design idea, outline their fabrication methods, and discuss the role of special wettability on the separation. Finally, the challenges and outlook for the future of this subject are discussed.

Special wettable materials for oil/water separation

Adhesion of polymers

Oil leakage and the discharge of oil/water mixtures by domestic and industrial consumers have caused not only severe environmental pollution and a threat to all species in the ecosystem but also a huge waste of precious resources. Therefore, the separation of oil/water mixtures, especially stable emulsion, has become an urgent global issue. Recently, materials containing a special wettability feature for oil and water have drawn immense attention because of their potential applications for oil/water separation application. In this paper, we systematically summarize the fundamental theories, separation mechanism, design strategies, and recent developments in materials with special wettability for separating stratified and emulsified oil/water mixtures. The related wetting theories that unveil the physical underlying mechanism of the oil/water separation mechanism are proposed, and the practical design criteria for oil/water separation materials are provided. Guided by the fundamental design criteria, various porous materials with special wettability characteristics, including those which are superhydrophilic/underwater superoleophobic, superhydrophobic/superoleophilic, and superhydrophilic/in-air superoleophobic, are systemically analyzed. These superwetting materials are widely employed to separate oil/water mixtures: from stratified oil/water to emulsified ones. In addition, the materials that implement the demulsification of emulsified oil/water mixtures via the ingenious design of the multiscale surface morphology and construction of special wettability are also discussed. In each section, we introduce the design ideas, base materials, preparation methods, and representative works in detail. Finally, the conclusions and challenges for the oil/water separation research field are discussed in depth.

Separation Mechanism and Construction of Surfaces with Special Wettability for Oil/Water Separation.

Adhesion phenomena in bonded joints

A critical evaluation of the binary and ternary solid-oil-water and solid-water-oil interaction.

Critical evaluation of the surface energy components of solids

Adsorption of organic probes on silica through Lewis interactions: a comparison of experimental results and quantum chemical calculations.

Alternative models for determining the surface energy components in offset printing.

Alternative methods to evaluate the surface energy components of ink-jet paper

B. Granqvist

Papers

A critical evaluation of the binary and ternary solid-oil-water and solid-water-oil interaction.

Critical evaluation of the surface energy components of solids

Adsorption of organic probes on silica through Lewis interactions: a comparison of experimental results and quantum chemical calculations.

Alternative models for determining the surface energy components in offset printing.

Alternative methods to evaluate the surface energy components of ink-jet paper