A separation membrane structure comprises a porous support, a first separation membrane formed on the porous support, and a second separation membrane formed on the first separation membrane. The first separation membrane has an average pore diameter of greater than or equal to 0.32 nm and less than or equal to 0.44 nm. The second separation membrane includes addition of at least one of a metal cation or a metal complex that tends to adsorb nitrogen in comparison to methane.

Provided is an ionic compound, which can be formulated into an ionic solution for extracting hydrophobic proteins. The ionic solution is free of alcohol and thus advantageous for later examinations. Also provided is an anti-nonspecific protein adsorption zwitterionic compound, which can be coated on a substrate to form an anti-nonspecific protein adsorption element.

A filter medium is provided with a layer (A) provided with non-impregnated active carbon, a layer (B) with a solid carrier material that is impregnated with a permanganate salt, and a layer (C) with alkaline impregnated active carbon. The layer (B) and the layer (C) are arranged such that a gas flowing through the filter medium flows through the layer (B) before flowing through the layer (C). The layer (A) is arranged such that the gas flowing through the filter medium flows through the layer (A) before flowing through the layer (B) or the gas flowing through the filter medium flows through the layer (A) after flowing through the layer (C).

Described herein are passive samplers, making of such samplers, and methods of use. In an example embodiment, a passive sampling membrane comprises, for example, a continuous mesoporous sequestration media having a sequestration phase and a support membrane configured to support the sequestration phase. The sequestration phase may include a hydrophobic region and a hydrophilic region. The continuous mesoporous sequestration media may be configured to simultaneously sequester polar and non-polar organic substances.

A gel particle film of amino group-having polymer compound particles has a large acid gas absorption amount and desorption amount per unit volume, and has a high acid gas absorption rate and desorption rate per unit mass, and further has high stability. A gas absorber having the gel particle film supported on a carrier is useful as an acid gas separation material having good energy efficiency.

A method for producing a coating film-forming composition for lithography, including a step for passing a liquid through a filter cartridge. The filter cartridge is obtained by layering more than one type of filtration base fabrics or winding same around a hollow inner tube, wherein: the fabrics are non-woven fabrics in which metal-adsorbing groups are chemically bonded to polyolefin fibers; the fabrics contain non-woven fabric layers A and B; layer A is configured from polyolefin fibers to which sulfonic acid groups are chemically bonded as metal-adsorbing groups; and layer B is configured from polyolefin fibers to which at least one type selected from among amino groups, N-methyl-D-glucamine groups, iminodiacetic acid groups, iminodiethanol groups, amidoxime groups, phosphoric acid groups, carboxylic acid groups and ethylenediamine triacetic acid groups chemically bonded as metal-adsorbing groups. Thus, the amount of metal impurities that are the cause of minute defects on a wafer can be reduced.

Filter media comprising adsorptive particles are generally described. In some embodiments, the adsorptive particles are present in a relatively large amount, in a layer discrete from one or more other layers and/or fiber webs also present in the filter media, and/or in a layer that comprises a relatively low amount of fibers. In some embodiments, the filter media further comprises a non-woven fiber web comprising fibers with relatively small diameters.

A device having a semiconductor nanomaterial surface, formed on a dielectric layer, having a conductive material under the dielectric layer, wherein a potential across the dielectric modified an absorption property of the semiconductor nanomaterial. A method of controlling a property of surface is provided, comprising: providing a device having a semiconductor nanomaterial having the surface, formed on a dielectric layer, having a conductive material under the dielectric layer; and controlling an electrostatic field at the semiconductor nanomaterial to modify at least one property of the surface with respect to molecules. The property may be absorption or wetting, for example.

An absorbent article (1) comprising a top sheet (2), a back sheet (3) and an absorbent body (11) provided therebetween, wherein; the absorbent body (11) has a high-rigidity part (12) and a low-rigidity part (13); the high-rigidity part (12) and the low-rigidity part (13) extend in the front-rear direction, respectively, and are arranged alternately in the width direction; an anti-slipping member (7) is provided on a non-skin facing side of the back sheet (3); and the anti-slipping member (7) is provided so as to astride a first high-rigidity side part (12A) closest to one end in the width direction of the absorbent body (11) and a second high-rigidity side part (12B) closest to the other end in the width direction of the absorbent body (11), and not to extend outward in the width direction from the first high-rigidity side part (12A) and the second high-rigidity side part (12B).

A method for purifying dye-containing wastewater based on a porous-polymer-modified metal carbon nanotube membrane includes: (1) preparing the porous-polymer-modified metal carbon nanotube membrane; and (2) passing the dye-containing wastewater through the porous-polymer-modified metal carbon nanotube membrane to remove dyes in the dye-containing wastewater. A device for purifying dye-containing wastewater is also disclosed. The device includes the porous-polymer-based metal carbon nanotube membrane.