Abstract: A suction device including a casing having a central post extending through the casing. A flexible member is provided across a free end of the central post. One or more artificial muscles are housed within the casing and encircle the central post, each artificial muscle including a housing having a first wall and a second wall opposite the first wall. The housing having an electrode region adjacent an expandable fluid region, a dielectric fluid housed within the housing, and an electrode pair housed within the electrode region of the housing. The electrode pair includes a first electrode coupled to the first wall and a second electrode coupled to the second wall. The electrode pair is actuatable between a non-actuated state and an actuated state such that actuation from the non-actuated state to the actuated state directs the dielectric fluid into the expandable fluid region and deforms the flexible member to form a suction area at the free end of the central post.

Abstract: A programmable texture surface including one or more artificial muscles is provided. Each artificial muscle includes a housing having a first wall opposite a second wall and an electrode region adjacent an expandable fluid region. One or both of the first wall and the second wall include an interior tapered portion within the electrode region. A dielectric fluid is housed within the housing and an electrode pair is housed within the electrode region of the housing. The electrode pair includes a first electrode coupled to the first wall and a second electrode coupled to the second wall, such that at least one of the first electrode and the second electrode is coupled to the interior tapered portion. The electrode pair is actuatable between a non-actuated state and an actuated state such that actuation from the non-actuated state to the actuated state directs the dielectric fluid into the expandable fluid region.

Abstract: A variable stiffening device that includes a flexible envelope having a fluid chamber, a dielectric fluid housed within the fluid chamber, and an electrode stack that includes a plurality of electrodes and one or more abrasive strips. The electrode stack is housed within the fluid chamber and is configured to receive voltage. In addition, the one or more abrasive strips are each positioned between adjacent electrodes, such that when voltage is applied to the electrode stack thereby electrostatically drawing adjacent electrodes together, the one or more abrasive strips generate frictional engagement between adjacent electrodes to actuate the variable stiffening device from a relaxed state to a rigid state.

Abstract: A fluid transport system that includes a magnetic shape memory pipe having an input end opposite an output end and an outer surface opposite an inner surface. The inner surface defines an inner diameter of the magnetic shape memory pipe and the magnetic shape memory pipe includes a magnetic shape memory alloy. The fluid transport system further includes one or more magnetic field generating devices surrounding the outer surface of the magnetic shape memory pipe and configured to generate a control magnetic field that, when applied to a region of the magnetic shape memory pipe, alters the inner diameter of the region of the magnetic shape memory pipe.

Abstract: A novel class of reagents, useful for synthesis of elemental nanoparticles, includes at least one element, formally in oxidation state zero in complex with a hydride molecule. The reagents can optionally include an additional ligand incorporated into the complex. Elemental nanoparticles are synthesized by adding solvent to the reagent, optionally with a free ligand and/or a monoatomic cation.

Abstract: A novel class of reagents, useful for synthesis of elemental nanoparticles, includes at least one element, formally in oxidation state zero in complex with a hydride molecule. The reagents can optionally include an additional ligand incorporated into the complex. Elemental nanoparticles are synthesized by adding solvent to the reagent, optionally with a free ligand and/or a monoatomic cation.

Abstract: A composition and its method of production are provided. The composition includes at least one zero-valent metallic element atom in complex with at least one hydride molecule. The method of production includes ball-milling an elemental metal in a high-surface area form, with a hydride. The composition can be useful as a reagent for the synthesis of zero-valent metallic elemental nanoparticles.

Abstract: A reagent and its method of production are provided. The reagent includes at least one zero-valent atom, whether metal, metalloid, or non-metal, in complex with at least one hydride molecule. The method of production includes ball-milling a mixture which includes an elemental (i.e. zero-valent) material and a hydride. In some cases, the elemental material is a non-metal such as carbon. The reagent can be useful as a reagent for the synthesis of elemental nanoparticles composed of zero-valent metal, metalloid, or non-metal.

Abstract: A reagent and its method of production are provided. The reagent includes at least one zero-valent atom, whether metal, metalloid, or non-metal, in complex with at least one hydride molecule. The method of production includes ball-milling a mixture which includes an elemental (i.e. zero-valent) material and a hydride. In some cases, the elemental material is a non-metal such as carbon. The reagent can be useful as a reagent for the synthesis of elemental nanoparticles composed of zero-valent metal, metalloid, or non-metal.

Abstract: A composition and its method of production are provided. The composition includes at least one zero-valent metallic element atom in complex with at least one hydride molecule. The method of production includes ball-milling an elemental metal in a high-surface area form, with a hydride. The composition can be useful as a reagent for the synthesis of zero-valent metallic elemental nanoparticles.

Abstract: A thermoelectric material that comprises a binary main group matrix material and nano-particles and/or nano-inclusions of metal oxide dispersed therein, and has electrical properties of ternary doped materials. A process for making the thermoelectric material that includes reacting a reduced metal precursor with an oxidized metal precursor in the presence of nanoparticles.

Abstract: A thermoelectric material that comprises a binary main group matrix material and nano-particles and/or nano-inclusions of metal oxide dispersed therein, and has electrical properties of ternary doped materials. A process for making the thermoelectric material that includes reacting a reduced metal precursor with an oxidized metal precursor in the presence of nanoparticles.

Abstract: A thermoelectric material that comprises a ternary main group matrix material and nano-particles and/or nano-inclusions of transition metal oxide dispersed therein. A process for making the thermoelectric material that includes reacting a reduced metal precursor with an oxidized metal precursor in the presence of transition metal oxide nanoparticles.