The invention concerns a method for producing a chromatography-enrichment column, the method comprising the following steps: (a) depositing at least one layer of desired particles, which may be identical or different, and are intended to constitute the stationary phase, in a compact assembly, on the flat surface of a substrate; (b) crosslinking the layer in at least the regions corresponding to the desired shape of the enrichment column to be obtained; (c) impregnating the layer with a light radiation-sensitive material; (d) insolating the layer obtained in step (c) so as to form insolated regions of which the shape corresponds to the desired internal shape of the enrichment column, if the light radiation-sensitive material behaves like a positive resin or to form non-insolated regions of which the shape corresponds to the desired internal shape of the enrichment column if the light radiation-sensitive material behaves like negative resin; and (e) eliminating the light radiation-sensitive material in the zones corresponding to the internal shape of the enrichment column. The invention is used in particular in the field of chemical analysis.

A film forming apparatus, a substrate processing apparatus, and a device manufacturing method are provided, which improve the film thickness uniformity of a thin film that is formed on a substrate by spraying a thin film material. The film forming apparatus which forms a thin film on a substrate is provided with a nozzle that sprays a thin film material and an exhaust unit that discharges a gas. An exhaust port of the exhaust unit is arranged on a side that is opposite to the direction in which the gravity acts with respect to the substrate. The substrate processing apparatus performs a predetermined process on the substrate using the film forming apparatus. The device manufacturing method manufactures a device using the film forming apparatus.

This disclosure provides systems, methods, and apparatus related to simulated soiling and weathering of materials. In one aspect, a soiling mixture may include an aqueous suspension of various amounts of salt, soot, dust, and humic acid. In another aspect, a method may include weathering a sample of material in a first exposure of the sample to ultraviolet light, water vapor, and elevated temperatures, depositing a soiling mixture on the sample, and weathering the sample in a second exposure of the sample to ultraviolet light, water vapor, and elevated temperatures.

A wire grid polarizer (WGP) can have a phosphonate conformal-coating to protect the WGP from at least one of the following: corrosion, dust, and damage due to tensile forces in a liquid on the WGP. The conformal-coating can include a chemical:

##STR00001##

where R.sup.1 can include a hydrophobic group, Z can include a bond to the ribs, and R.sup.5 can be any suitable chemical element or group.

A method of applying a phosphonate conformal-coating over a WGP can include exposing the WGP to (R.sup.1).sub.iPO(R.sup.4).sub.j(R.sup.5).sub.k, where: i is 1 or 2, j is 1 or 2, k is 0 or 1, and i+j+k=3; each R.sup.1 can independently include a hydrophobic group; R.sup.4 can include a phosphonate-reactive-group; each R.sup.6 can independently include an alkyl group, an aryl group, or combinations thereof; and each R.sup.5, if any, can independently be any suitable chemical element or group.

A wire grid polarizer (WGP) can have a phosphonate conformal-coating to protect the WGP from at least one of the following: corrosion, dust, and damage due to tensile forces in a liquid on the WGP. The conformal-coating can include a chemical: ##STR00001##
where R.sup.1 can include a hydrophobic group, Z can be a bond to the ribs, and R.sup.5 can be any suitable chemical element or group. A method of applying a phosphonate conformal-coating over a WGP can include exposing the WGP to (R.sup.1).sub.iPO(R.sup.4).sub.j(R.sup.5).sub.k, where: i is 1 or 2, j is 1 or 2, k is 0 or 1, and i+j+k=3; each R.sup.1 can independently be a hydrophobic group; R.sup.4 can be a phosphonate-reactive-group; each R.sup.6 can independently be an alkyl group, an aryl group, or combinations thereof; and each R.sup.5, if any, can independently be any suitable chemical element or group.

A film forming apparatus, a substrate processing apparatus, and a device manufacturing method are provided, which improve the film thickness uniformity of a thin film that is formed on a substrate by spraying a thin film material. The film forming apparatus which forms a thin film on a substrate is provided with a nozzle that sprays a thin film material and an exhaust unit that discharges a gas. An exhaust port of the exhaust unit is arranged on a side that is opposite to the direction in which the gravity acts with respect to the substrate. The substrate processing apparatus performs a predetermined process on the substrate using the film forming apparatus. The device manufacturing method manufactures a device using the film forming apparatus.

The present invention pertains to a method for producing a graphene-coated steel sheet, the method comprising the steps of: modifying the surface of the steel sheet so that the surface is negatively charged; forming a positively-charged first graphene oxide layer on the surface-modified steel sheet; forming a negatively-charged second graphene oxide layer on the first graphene oxide layer; and heat-treating the steel sheet on which the first and second graphene oxide layers are formed. The present invention provides a graphene coating method which can be easily applied to large-area coating through a simple process without a special dispersant or binder, and has the effect of allowing the excellent physical properties of graphene to be more efficiently exhibited.

The present invention pertains to a method for producing a graphene-coated steel sheet, the method comprising the steps of: modifying the surface of the steel sheet so that the surface is negatively charged; forming a positively-charged first graphene oxide layer on the surface-modified steel sheet; forming a negatively-charged second graphene oxide layer on the first graphene oxide layer; and heat-treating the steel sheet on which the first and second graphene oxide layers are formed. The present invention provides a graphene coating method which can be easily applied to large-area coating through a simple process without a special dispersant or binder, and has the effect of allowing the excellent physical properties of graphene to be more efficiently exhibited.

The present invention relates to a process for producing a coating from an aqueous, radiation-curable coating composition, wherein the process comprises the steps in the sequence (1) to (4): (1) applying an aqueous, radiation-curable coating composition on a surface of a substrate, (2) drying the aqueous, radiation-curable coating composition, affording an at least partially dried coating composition, (3) irradiating the at least partially dried coating composition with UV light having a wavelength s 220 nm under inert atmosphere, followed by (4) irradiating with UV light having a wavelength 300 nm or with E-beam, wherein the aqueous, radiation-curable coating composition is a dispersion comprising: (A) at least one water-dispersible polyurethane (A), wherein the polyurethane (A) has a urea group (NHCONH) concentration of at least 0.1 milli-equivalents per g of polyurethane (A) and of at most 2.6 milli-equivalents per g of polyurethane (A) and the polyurethane (A) is essentially free of radiation-curable, ethylenically unsaturated bonds, (B) at least one radiation-curable diluent (B) with a molar mass less than 750 g/mol and with an acrylate functionality of from 2 to 5, and (C) water and optionally organic solvent, whereby the optional organic solvent is present in an amount of at most 30 wt. %, based on the total amount of water and organic solvent, wherein the amount of (A) is from 30 to 85 wt. % and the amount of (B) is from 15 to 70 wt. %, based on the total amount of (A) and (B).

A treatment system, including a conveyor bed configured to transport a plurality of products; a brushing device located along the conveyor bed and having one or more brushes that include a first antimicrobial compound; a surface treatment device including a lamp configured to emit light of a peak wavelength directed toward a portion of the conveyor bed; and a coating device configured to deliver a coating mixture onto the plurality of products on the conveyor bed.