Provided herein are nanoparticulate coated structures and methods of making structures. The structures comprise a support element, a nanoparticulate layer, and a binder disposed on the support element, wherein the binder comprises an alkali silicate or borate. In addition, methods of making the structures and uses of the described structures are described herein.

A superhydrophobic surface includes a plurality of microfeatures disposed on a substrate and a gas generator disposed within the microfeatures, the gas generator configured to generate a gas within the microfeatures. Gas is generated within the microfeatures when at least a portion of the microfeatures is in a wetted state to restore the microfeatures to a dewetted state. Gas generation is self-regulating in that gas generation automatically starts when a wetted condition exists and stops when sufficient gas has been generated to recover a dewetted state that restores superhydrophobicity.

A superhydrophobic surface includes a plurality of microfeatures disposed on a substrate and a gas generator disposed within the microfeatures, the gas generator configured to generate a gas within the microfeatures. Gas is generated within the microfeatures when at least a portion of the microfeatures is in a wetted state to restore the microfeatures to a dewetted state. Gas generation is self-regulating in that gas generation automatically starts when a wetted condition exists and stops when sufficient gas has been generated to recover a dewetted state that restores superhydrophobicity.

Layer-by-layer thickness control of an electroplated film can be achieved by using a cyclic deposition process. The cyclic process involves forming a layer (or partial layer) of hydrogen on a surface of the substrate, then displacing the layer of hydrogen with a layer of metal. These steps are repeated a number of times to deposit the metal film to a desired thickness. Each step in the cycle is self-limiting, thereby enabling atomic level thickness control.

An automotive member or a feed oil pipe includes: a member made of a ferritic stainless steel containing predetermined components containing 10.5% to 18.0% of Cr in mass %; a metal fitting made of an aluminized stainless steel sheet, the metal fitting being attached to the member; and a gap structure defined between the member and the metal fitting, the gap structure being exposed to a chloride environment, where the metal fitting has an Al-plating weight per unit area of 20 g/m.sup.2 or more and 150 g/m.sup.2 or less on a surface corresponding to a gap of the gap structure, and surfaces of the metal fitting and the non-aluminized member other than the gap are coated with a cation electrodeposition coating film having a thickness of 5 m to 35 m.

An automotive member or a feed oil pipe includes: a member made of a ferritic stainless steel containing predetermined components containing 10.5% to 18.0% of Cr in mass %; a metal fitting made of an aluminized stainless steel sheet, the metal fitting being attached to the member; and a gap structure defined between the member and the metal fitting, the gap structure being exposed to a chloride environment, where the metal fitting has an Al-plating weight per unit area of 20 g/m.sup.2 or more and 150 g/m.sup.2 or less on a surface corresponding to a gap of the gap structure, and surfaces of the metal fitting and the non-aluminized member other than the gap are coated with a cation electrodeposition coating film having a thickness of 5 m to 35 m.

An implant (5, 13) and/or a unit (9), e.g. spacer sleeve, belonging to said implant is/are intended to extend through a hole (4) formed in a jaw bone (2) and through soft tissue (3) belonging to the jaw bone and to comprise one or more outer layers of principally titanium dioxide. Each layer consists of crystalline titanium dioxide which largely or completely assumes the anatase phase. The invention also relates to a method for production of such a dental implant (5, 13) and/or of a unit (9) belonging to it, which has one or more outer layers of titanium dioxide. The method is an anodic oxidation method in which the part or parts bearing the outer layer(s) is/are applied to electrolyte under voltage, e.g. comprising sulfuric acid and phosphoric acid, and the voltage (U) and the dwell time of the part or parts in the electrolyte are chosen such that titanium dioxide, largely or completely assuming the crystalline anatase phase, is formed. Excellent bone guidance and soft tissue integration can be achieved in this way.

The planchet holder for electrodeposition of materials includes a container cover configured to securely fit over the mouth of a beaker. An elongate suspension post passes through a through-hole in the cover a predetermined distance, and a holder assembly is coupled to the suspension post to be suspended within the beaker at a select height from the bottom of the beaker. A planchet receptacle extends axially from a body of the holder assembly, and a substrate recess is formed at a distal end of the planchet receptacle for selective placement of a planchet. An endcap is secured onto the planchet receptacle to securely capture the planchet, and a port in the endcap exposes one face of the planchet for electrodeposition of a material. The planchet holder holds the planchet stationary within the beaker and exposes only one face for electrodeposition and subsequent analysis, thereby reducing time and costs.

The planchet holder for electrodeposition of materials includes a container cover configured to securely fit over the mouth of a beaker. An elongate suspension post passes through a through-hole in the cover a predetermined distance, and a holder assembly is coupled to the suspension post to be suspended within the beaker at a select height from the bottom of the beaker. A planchet receptacle extends axially from a body of the holder assembly, and a substrate recess is formed at a distal end of the planchet receptacle for selective placement of a planchet. An endcap is secured onto the planchet receptacle to securely capture the planchet, and a port in the endcap exposes one face of the planchet for electrodeposition of a material. The planchet holder holds the planchet stationary within the beaker and exposes only one face for electrodeposition and subsequent analysis, thereby reducing time and costs.

A gas sensor operable at ambient conditions, the sensor includes functionalized feather-like tellurium (Te) nanostructures on single-walled carbon nanotube (SWNTs) networks.