A method is provided for at least partially preventing discolouration of a substrate by a plasma coating process, by diffusing a plasma prior to and/or during depositing of said plasma on said substrate to form a coating. Also provided is a plasma coating apparatus comprising a plasma diffuser for homogenizing a plasma density nearby a substrate to be coated.

A method is provided for at least partially preventing discolouration of a substrate by a plasma coating process, by diffusing a plasma prior to and/or during depositing of said plasma on said substrate to form a coating. Also provided is a plasma coating apparatus comprising a plasma diffuser for homogenizing a plasma density nearby a substrate to be coated.

In some aspects, the inventive subject matter contemplates: providing a substrate; providing a biomaterial to be affixed to the substrate; and subjecting the substrate and biomaterial to reactive species from a plasma generated by an atmospheric plasma apparatus until the biomaterial affixes to the substrate. The biomaterial may be silk or wool polypeptide. The biomaterial is deposited as a monomeric film on the surface of the substrate before the substrate is subjected to the reactive species of the plasma. Once the substrate with the film of biomaterial is subjected to the reactive species, the reactive species facilitates the polymerization of the film as a coating on the underlying portion of substrate. The resulting coated substrates are novel constructs that have improved attributes based on the biomaterial selected for use. For example, silk proteins may be used improve the hand or strength of textile materials.

In some aspects, the inventive subject matter contemplates: providing a substrate; providing a biomaterial to be affixed to the substrate; and subjecting the substrate and biomaterial to reactive species from a plasma generated by an atmospheric plasma apparatus until the biomaterial affixes to the substrate. The biomaterial may be silk or wool polypeptide. The biomaterial is deposited as a monomeric film on the surface of the substrate before the substrate is subjected to the reactive species of the plasma. Once the substrate with the film of biomaterial is subjected to the reactive species, the reactive species facilitates the polymerization of the film as a coating on the underlying portion of substrate. The resulting coated substrates are novel constructs that have improved attributes based on the biomaterial selected for use. For example, silk proteins may be used improve the hand or strength of textile materials.

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.

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.

A process for modifying a silicone elastomeric-based surface of a textile article where the coefficient of friction (COF) of the silicone elastomeric-based surface is generally reduced by at least 5% is disclosed. The process comprises subjecting the silicone elastomeric-based surface of the textile article to vacuum ultraviolet (UV) radiation.

A process for modifying a silicone elastomeric-based surface of a textile article where the coefficient of friction (COF) of the silicone elastomeric-based surface is generally reduced by at least 5% is disclosed. The process comprises subjecting the silicone elastomeric-based surface of the textile article to vacuum ultraviolet (UV) radiation.

One or more nanofiber yarns can be placed in contact with one or more nanofiber sheets. The nanofiber yarns, which include single-ply and multi-ply nanofiber yarns, provide added mechanical stability to a nanofiber sheet that decreases the likelihood of a nanofiber sheet wrinkling, folding, or otherwise becoming stuck to itself. Furthermore, the nanofiber yarns integrated with the nanofiber sheet can also act as a mechanism to prevent the propagation of tears through the nanofiber sheet. In some cases, an infiltrating material can be infiltrated into interstitial spaces defined by the nanofibers within both the nanofiber yarns and the nanofiber sheets. The infiltrating material can then form a continuous network throughout the nanofiber yarns and the nanofiber sheet.

One or more nanofiber yarns can be placed in contact with one or more nanofiber sheets. The nanofiber yarns, which include single-ply and multi-ply nanofiber yarns, provide added mechanical stability to a nanofiber sheet that decreases the likelihood of a nanofiber sheet wrinkling, folding, or otherwise becoming stuck to itself. Furthermore, the nanofiber yarns integrated with the nanofiber sheet can also act as a mechanism to prevent the propagation of tears through the nanofiber sheet. In some cases, an infiltrating material can be infiltrated into interstitial spaces defined by the nanofibers within both the nanofiber yarns and the nanofiber sheets. The infiltrating material can then form a continuous network throughout the nanofiber yarns and the nanofiber sheet.