Abstract: An apparatus (e.g. a shape memory device) and/or methods thereof that may include employing a nano-particle layer, a linking agent layer, and a shape memory layer. An electrode for heating shape memory material during shape transitions of the shape memory layer may include the nano-particle layer and the linking agent layer. The nano-particle layer may include conductive nano-size particles (e.g. gold clusters having a diameter less than 100 nanometers or less than 50 nanometers). The electrode may be substantially resilient to deformation of the shape memory material due to individual bonding of individual particles of the nano-particle layer to the shape memory layer and/or the linking agent layer.

Abstract: An apparatus (and a method of making an apparatus) that includes a flexible functional material. The flexible functional material includes nano-particle layer(s) and linking agent layer(s). The nano-particle layer(s) are bonded to the linking agent layer(s). The nano-particle layer(s) and/or linking agent layer(s) are deposited by being sprayed. Since nano-particle layer(s) and/or linking agent layer(s) may be deposited by being sprayed, a flexible functional material may be easily formed on structures (e.g. such as external aircraft parts) to create a conductive surface. Through spraying, deposition may be efficient and effective and allow for implementations which are impractical and/or not possible with bulk metal materials.

Abstract: An apparatus includes a flexible base material and a flexible material formed on the flexible base material. Both the flexible base material and the flexible material have shrinkable and/or stretchable properties. The flexible base material may include a shrinkable polymer (e.g. PVC/PET or “shrink wrap”), which may shrink up to 500%. The flexible base material may include a stretchable polymer (e.g. Mylar), which may be stretched by at least 1000%. These stretchable and shrinkable properties may be exhibited without substantial functional degradation of either the flexible base material and/or the flexible material layer.

Abstract: The present invention relates to methodologies for the self-assembly of nanoparticles onto a release support that is capable of covalent integration into flexible free-standing films. Such films display useful constitutive properties, such as permittivity, permeability, electrical conductivity, thermal conductivity, and nonlinear optic properties. The type of property is dependant upon the type of nanoparticle incorporated into the compliant polymeric matrix. The compliant matrix may be any material that reacts with the components in the nanoparticle film and may be separated from the release substrate. The nanoparticles may be dispersed uniformly or spatially patterned throughout the self-assembled film.

Abstract: The present invention relates to methodologies for the self-assembly of nanoparticles onto a release support that is capable of covalent integration into flexible free-standing films. Such films display usefull constitutive properties, such as permittivity, permeability, electrical conductivity, thermal conductivity, and nonlinear optic properties. The type of property is dependant upon the type of nanoparticle incorporated into the compliant polymeric matrix. The compliant matrix may be any material that reacts with the components in the nanoparticle film and may be separated from the release substrate. The nanoparticles may be dispersed uniformly or spatially patterned throughout the self-assembled film.

Abstract: The present invention relates to methodologies for the self-assembly of nanoparticles onto a release support that is capable of covalent integration into flexible free-standing films. Such films display usefull constitutive properties, such as permittivity, permeability, electrical conductivity, thermal conductivity, and nonlinear optic properties. The type of property is dependant upon the type of nanoparticle incorporated into the compliant polymeric matrix. The compliant matrix may be any material that reacts with the components in the nanoparticle film and may be separated from the release substrate. The nanoparticles may be dispersed uniformly or spatially patterned throughout the self-assembled film.