A method is provided to form a dust mitigation coating that also mitigates or repels water, ice, and other liquids. Techniques to coat the surfaces of equipment and items with these dust, liquid, and ice mitigation coatings, minimize or eliminate mission problems caused by dust, liquid, or ice accumulation, particularly in outer space or on another planetary body or moon. Further, the dust mitigation coatings exhibit a Lotus-like effect, making the coated surfaces ultra-hydrophobic. The present invention is also directed to techniques for improving the functioning of terrestrial-based equipment and systems where dust, liquid, or ice accumulation is a problem, such as in hospitals and other health contexts, to prevent contamination.

The present disclosure provides a biomimetic composite that includes a plurality of nanostructures each having at least one axial geometry region comprising an inorganic material. The nanostructures may be a plurality of substantially aligned (e.g., in a vertical orientation) axial geometry nanowires comprising zinc oxide or alternatively hedgehog-shaped nanoparticles with needles comprising zinc oxide. A polymeric matrix disposed in void regions defined between respective nanostructures of the plurality of nanostructures. The biomimetic composite exhibits a viscoelastic figure of merit (VFOM) of greater than or equal to about 0.001 up to about 0.6 or greater. Methods of making such biomimetic composites are also provided.

The present disclosure provides a composite structure and associated method for preparing a composite substrate comprising an inorganic coating that is adhered to an organic-based substrate via an adhesion promoting agent comprising a molecule having a urea moiety at one end of the molecule and an alkoxysilane moiety at the other end of the molecule. The use of adhesion promoting agent having at least one of an amine or imine moiety and an alkoxysilane moiety promotes tight adhesion of the inorganic coating to the substrate.

An epilamization agent containing at least one compound including at least hydrophobic and oleophobic moieties arranged to impart epilame properties to the compound, and at least one hydrophilic moiety arranged to make the compound soluble in aqueous medium, the hydrophilic moiety being linked to the compound by at least one cleavable group. A method for coating a substrate with epilame, including: preparing an aqueous epilamization bath by solubilising such an epilamization agent, placing the substrate in contact with the epilamization agent in the epilamization bath, separating the hydrophilic moiety from the epilamization agent by cleavage, rinsing the substrate to eliminate the hydrophilic residues from the hydrophilic moiety and drying.

Methods and apparatus for removing deposits in self-assembled monolayer (SAM) based selective deposition process schemes using cryogenic gas streams are described. Some methods include removing deposits in self-assembled monolayer (SAM) based selective depositions by exposing the substrate to cryogenic aerosols to remove undesired deposition on SAM protected surfaces. Processing chambers for cryogenic gas assisted selective deposition are also described.

The present invention provides a drug-loaded tissue adhesive film, comprising alternately superposed cationic layers and anionic layers, at least one of the cationic layers and the anionic layers being a drug layer, or at least one of the cationic layers and the anionic layers containing a drug with charges. The provided drug-loaded tissue adhesive film has good tissue adhesiveness, biocompatibility, degradable absorption, and stability, and the physical and chemical properties of the drug-loaded tissue adhesive film can be adjusted by adjusting material compositions.

Implementations described herein relate to apparatus and methods for self-assembled monolayer (SAM) deposition. Apparatus described herein includes processing chambers having various vapor phase delivery apparatus fluidly coupled thereto. SAM precursors may be delivered to process volumes of the chambers via various apparatus which is heated to maintain the precursors in vapor phase. In one implementation, a first ampoule or vaporizer configured to deliver a SAM precursor may be fluidly coupled to the process volume of a process chamber. A second ampoule or vaporizer configured to deliver a material different from the SAM precursor may also be fluidly coupled to the process volume of the process chamber.

The elastomeric electrode includes: a stretchable substrate 10 having wrinkles formed on one surface thereof, the peaks C and valleys T of the wrinkles being repeated; a wrinkled metal nanoparticle layer 20 including metal nanoparticles 21 and formed by deposition of the metal nanoparticles along the wrinkles of the substrate 10; and a wrinkled monomolecular layer 30 including a monomolecular material having one or more amine groups (—NH.sub.2) and formed by deposition of the monomolecular material onto the metal nanoparticle layer 20. Also disclosed is a method for preparing the elastomeric electrode.

Disclosed is a method of manufacturing a surface-modified polymer film, including forming a hydroxyl group (—OH) on the surface of a polymer film by subjecting the polymer film to light irradiation and surface treatment with a photoacid generator. The polymer film can be introduced with a hydroxyl group (—OH) group using a photoacid generator, thereby modifying the surface of the polymer film without damage to the polymer film. Also, an organic electronic device including the surface-modified polymer film can be improved in electrical characteristics and stability.

Methods and apparatus for removing deposits in self-assembled monolayer (SAM) based selective deposition process schemes using cryogenic gas streams are described. Some methods include removing deposits in self-assembled monolayer (SAM) based selective depositions by exposing the substrate to cryogenic aerosols to remove undesired deposition on SAM protected surfaces. Processing chambers for cryogenic gas assisted selective deposition are also described.