A polypropylene composition (PC) comprising: a. from 95.0 to 99.99 wt.-%, of a polypropylene (PP), preferably a propylene homopolymer (HPP); and b. from 0.01 to 5.0 wt.-%, of a compound according to Formula (I), wherein each R is independently selected from C.sub.1 to C.sub.6 alkylene, C.sub.2 to C.sub.6 alkenylene and a single bond, each R is independently selected from H and C.sub.1 to C.sub.6 alkyl, each R is independently selected from H and C.sub.1 to C.sub.22 alkyl, wherein each alkylene, alkenylene and alkyl group may optionally be substituted by deuterium or fluorine, and the two substituents on the central benzene ring may be either positioned in an ortho, meta or para relationship; wherein the polypropylene composition (PC) has an MFR.sub.2 of from 400 to 5000 g/10 min and a melting temperature Tm of from 140 to 170 C.

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A piezoelectric fabric can include: a non-woven, continuous fiber mat comprising: a polymer; and a plurality of piezoelectric ceramic particles. The piezoelectric fabric can be produced by electrospinning. The method of electrospinning can include: forming a continuous fiber of material comprising: flowing a fluid through a needle, wherein the fluid comprises: the polymer; a base fluid; and the piezoelectric ceramic particles; and applying a voltage to create an electric field between a tip of the needle and a collector during fluid flow; and collecting the continuous fiber on the collector. The piezoelectric fabric can exhibit improved performance and piezo thermal stability.

A conjugate fiber includes two or more types of polymers, and having a fiber cross section in which a plurality of interfaces is formed, in which the conjugate fiber has a value, which is obtained by dividing a sum of lengths of interfaces between two types of the polymers by an area of the fiber cross section, of 0.0010 nm.sup.?1 or more, and each of the interfaces is continuous in a fiber axis direction.

A carbon nanotube yarn is coated with polyacrylonitrile to form a coated carbon nanotube yarn. The polyacrylonitrile is converted to crystalline carbon to form a layered carbon fiber with a sheath of the crystalline carbon and a core of the carbon nanotube yarn.

Provided are a base cloth for a material and a manufacturing method therefor, the base cloth suppressing opening of a boundary portion between an expanding part and a non-expanding part when used in a bag body, having low dynamic air permeability, and being capable of exhibiting the characteristic of being unlikely to burst even at high temperatures. A fabric base cloth for a material according to the present invention is composed of fibers having a prescribed thread breaking strength value, and for which the cloth surface is not subjected to resin coating, laminating, or a resin impregnation treatment.

A system for incorporating ferromagnetic materials into several microwave application is described. The system employs a multi-layer substrate. A substrate for receiving microwave signals uses a base layer which has tunable elements and a nanofiber layer which uses magnetic nanotubes. The nanofibers have a high aspect ratio and the nanofiber layer is embedded in the base layer.

Skin-core structure fibers with both infrared and radar stealth, a preparation method therefor, and the use thereof are provided. The fibers are as follows: a core material of the skin-core structure fibers comprises the following raw materials in parts by weight: 10 parts of paraffin; 0.7-1.5 parts of an electromagnetic wave absorbent; and 1 part of a high-molecular polymer, wherein the electromagnetic wave absorbent is one or more of ferroferric oxide-intercalated graphene oxide, nano ferroferric oxide and carbon black, and wherein the skin-core structure fiber is obtained by spinning the core material with a skin-layer material.

The present invention provides a novel fiber suitable for an adsorbent for acidic gas. The fiber of the present invention includes a polymer having an amino group. With respect to the fiber, an adsorption amount of carbon dioxide when the fiber is caused to be in contact with mixed gas composed of carbon dioxide, nitrogen, and water vapor for 15 hours is 0.1 mmol/g or more, for example. Here, the carbon dioxide in the mixed gas has a concentration of 400 vol ppm, and the mixed gas has a temperature of 23? C. and a humidity of 50% RH.

Presented herein are active textile structures with selectively variable surface friction characteristics, methods for making/using such structures, and vehicle components fabricated with electronically controlled textile structures with modifiable surface friction characteristics. An active textile system for governing frictional force levels at an interface with a user or object is presented. The system includes a textile structure that is fabricated from interlaced first and second textile filaments. Each textile filament has a respective texture that exhibits a distinct coefficient of friction. The textile structure has an outer and/or upper contact surface at the interface with the user/object. An actuating element, which is connected to the textile structure, is operable to selectively transition the textile structure between first and second states. The first state includes the first textile filament defining the textile structure's outer contact surface, whereas the second state includes the second textile filament defining the outer contact surface.

A seat belt webbing (100) includes a plurality of strands of infra-red reflecting yarn (112). A plurality of strands of infra-red absorbing yarn (110) are interwoven with the strands of infra-red reflecting yarn (112) to form the webbing with a pattern that is identifiable when the webbing (100) is subjected to infra-red light. An infra-red absorbing yarn precursor masterbatch includes a thermoplastic and an infra-red absorber mixed therein. The mixture is cut into a plurality of pellets for subsequent addition to thermoplastic pellets. In a method of making a fabric an infra-red absorber is added to a thermoplastic to form a homogenous mixture, which is extruded and spun to form an infra-red absorbing yarn. The infra-red absorbing yarn along with infra-red reflecting yarn is woven to form the fabric that has an identifiable infra-red absorbing pattern therein.