Biomimetics is a freshly explored area of materials science that deals with the science of copying or improving upon that which is found in nature. Scientists commonly produce artificial materials with properties that improved from what occurs naturally. In this thesis, we demonstrate three types of novel functional nanomaterials inspired by moth eyes, gecko feet and rose petals. Moth eyes consist of quasi-close-packed nipples having heights and spacings typically of less than 300 nm, which reduces reflection from their compound eyes. We found, a metal whose oxide form has a higher ionic conductivity than alumina was used as an underlayer preceding an Al anodization process, the underlying metal would be also oxidized and thereby form metal–oxide nanostructures as Moth-eye structures. We modulate the metal–oxide nanomaterials to form, hollow-to-solid and hemisphere-to-cone nanostructure arrays. We employ subwavelength nanocone arrays as Moth-eyes structures for high-performance antireflection coatings. These oxide nanostructures greatly suppress reflectance over a large range of wavelengths and angles of incidence and display a good mechanical stability. Also, we introduce these nanocones as a new photoelectrode architecture for improved efficiency of dye-sensitized solar cells (DSSCs).A facile synthesis of self-organized hollow TiO2 nanocones under porous anodic alumina (PAA) featuring TiO2 nanotubes (NTs) within was grown directly on a fluorine-doped tin oxide (FTO) substrate. The novel structure combines two types of TiO2 materials—0-D nanocones and 1-D NTs—to benefits from a large contact area, direct electron transport path, and slow recombination of electrons. A gecko is the largest animal that can produce high dry-adhesion to support its weight with a high factor of safety. The secret of the gecko’s adhesive properties lies in the hairy microstructure and nanostructure of gecko feet. We designed the efficient method of an innovate structure for ideal dry adhesives. A taper anodic alumina oxide mold with a length of 1.3 μm and a diameter of 380 nm was fabricated using decoupling two-step hard-anodization process which was firstly reported by us. After molding, taper-shaped nanohair array with slanted angle was presented. The approach to fabricate angled taper nanohair arrays obtained an excellent directional, reusable, and water cleanable use in large area. A remarkably directional force exhibited by angled taper nanohair arrays was showing here with strong shear attachment (8 N/cm2) in the gripping direction and easy releasing (1.4 N/cm2) in the reverse direction. Unlike “Lotus effect”, the petal’s surface which has superhydrophobicity and high water adhesion was fascinated by scientists in recent years. The phenomenon is induced by the microscale convex and nanostructures upon the petal. To mimic the petal’s surface, we developed a bottom-up method by the simple acid texture technique to fabricate the superhydrophobic PDMS surface with high water adhesion and self-cleaning ability. The resulting petal-like PDMS had convexes about 30 μm in diameter, nanowrinkles around 500 nm in width and nanostructures less than 100 nm. A high water contact angle larger than 150° was displayed. Moreover, the petal-like PDMS exhibited the high water adhesion up to 35.8 N/m2. In addition, the two superhydrophobic surfaces from the acid texture technique allowed us to fabricate a modern nonresidual stamp. The superhydrophobic and water adhesive area is applicable to transport the dye from the stamp to a paper. The superhydrophobic and self-cleaning region avoids the adhesion of dye.