Abstract: A series elastic robotic limb may include an energy generator, an energy storage element, and a link assembly. The link assembly may include a plurality of links coupled, via one or more joints, at one or more pivot locations. The energy generator may output a first force that causes an accumulation of energy in the energy storage element while the link assembly is in a first configuration and transitions the link assembly from the first configuration to a second configuration. The energy storage element may release the energy accumulated in the energy storage element when the link assembly is in the second configuration. The link assembly in the second configuration may trigger a motion of the series elastic robotic limb by at least amplifying the first force output by the energy generator and a second force associated with the energy released from the energy storage element.

Abstract: A series elastic robotic limb may include an energy generator, an energy storage element, and a link assembly. The link assembly may include a plurality of links coupled, via one or more joints, at one or more pivot locations. The energy generator may output a first force that causes an accumulation of energy in the energy storage element while the link assembly is in a first configuration and transitions the link assembly from the first configuration to a second configuration. The energy storage element may release the energy accumulated in the energy storage element when the link assembly is in the second configuration. The link assembly in the second configuration may trigger a motion of the series elastic robotic limb by at least amplifying the first force output by the energy generator and a second force associated with the energy released from the energy storage element.

Abstract: A fabricated microstructure includes a base and one or more nano-structures disposed on one or more portions of the base to adhere to a contact surface. The one or more portions of the base with the one or more nano-structures are located on the base such that, when the one or more nano-structures adhere to the contact surface and an external force is applied to peel the base from the contact surface, the one or more nano-structures in the one or more portions of the base facilitate or resist peeling of the nano-structures from the contact surface.

Abstract: A method of forming an adhesive force includes removing a seta from a living specimen, attaching the seta to a substrate, and applying the seta to a surface so as to establish an adhesive force between the substrate and the surface. The seta is applied to the surface with a force perpendicular to the surface. The seta is then pulled with a force parallel to the surface so as to preload the adhesive force of the seta.

Abstract: A fabricated nano-structure includes a substrate, a supporting stalk, a node, and at least two spatular plate portions. The supporting stalk has a first end opposite a second end. The first end of the supporting stalk is connected to the substrate. The supporting stalk has a diameter range of about 50 nanometers to about 2 microns. A node is disposed at the second end of the supporting stalk. At least two spatular plate portions are connected to the node. The at least two spatular plate portions have planar geometries and are radially distributed about the node. The at least two spatular plate portions has a ratio of a maximum plate thickness to a maximum plate length of at most about 1:20. The maximum plate length is measured along a line from a boundary of the spatular plate portion to a centroid of the node. The maximum plate length is at least about 100 nanometers.

Abstract: Described herein is a microstructure having a substrate and a plurality of nano-fibers attached to the substrate. Each nano-fiber moves between the first and second states without an external mechanical load being applied to the nano-fibers. Each nano-fiber is configured to move between a first state and a second state in response to applied electricity, magnetism, chemical solution, heat, or light. Each nano-fiber is straight in the first state and curved in the second state, and when the nano-fibers are in the second state and in contact with a contact surface, the nano-fibers adhere to the contact surface.

Abstract: A tire has a curved tire surface and a nano-scale structure disposed on a portion of the curved tire surface. A contact patch on the curved tire surface contacts a contact surface as the tire rolls along the contact surface. The nano-scale structure has a base and a tip. The base is connected to the portion of the curved tire surface. The tip is disposed opposite the base. When the portion of the curved tire surface with the nano-scale structure is positioned away from the contact patch, the nano-scale structure is in a relaxed position. When the portion of the curved tire surface is rotated into the contact patch, the nano-scale structure is engaged with the contact surface. When the portion of the curved tire surface is rotated through the contact patch, the nano-scale structure is adhesively anchored to the contact surface with the nano-scale structure undergoing tension and compression.

Abstract: Described herein are fabricated microstructures to adhere in shear to a contact surface. A fabricated microstructure comprises a substrate and a plurality of nano-fibers attached to the substrate. The nano-fibers have an elasticity modulus E, an interfacial energy per unit length of contact w, a length L, a radius R, and are oriented at an angle ?o relative to the substrate. The length L of the nano-fibers is greater than 0.627?o R2(E/w)1/2 with ?o in radians. Also described herein is a method of forming a fabricated microstructure to adhere in shear to a contact surface and a method of adhering in shear a fabricated microstructure to a contact surface.

Abstract: A high performance piezoelectric actuator. The actuator includes a piezoelectric material exhibiting a selectively tapered width sufficient to enhance actuator fracture load capabilities. A passive material is disposed on or integrated with the piezoelectric material. A drive system is connected to the piezoelectric material. The drive system is capable of selectively applying an electric field to the piezoelectric material. In specific embodiment, the piezoelectric material includes a curved piezoelectric layer exhibits a default state of compression along a surface of the piezoelectric layer.

Abstract: A method for fabricating a piezoelectric actuator. The method includes using a mold to place a first portion of a piezoelectric actuator in compression and to place a second portion of the piezoelectric actuator in tension. In a more specific embodiment, the method further includes selecting piezoelectric and elastic passive layer materials; choosing actuator dimensions with reference to desired actuator performance parameters; and then employing a curved mold to form a piezoelectric actuator with the desired dimensions. The piezoelectric actuator exhibits a first surface with compressive stresses caused by curing of the actuator via the curved mold.

Abstract: A fabricated microstructure includes a base and one or more nano-structures disposed on one or more portions of the base to adhere to a contact surface. The one or more portions of the base with the one or more nano-structures are located on the base such that, when the one or more nano-structures adhere to the contact surface and an external force is applied to peel the base from the contact surface, the one or more nano-structures in the one or more portions of the base facilitate or resist peeling of the nano-structures from the contact surface.

Abstract: A fabricated microstructure comprising at least one protrusion capable of providing an adhesive force at a surface of between about 60 and 2,000 nano-Newtons. A stalk supports the protrusion at an oblique angle relative to a supporting surface. The microstructure can adhere to different surfaces.

Abstract: A surgical device capable of adhering to tissues is disclosed herein. The surgical device includes a micromechanical frame moveably linked to a plurality of micromechanical appendages. A plurality of nano-fibers that mimic adhesion of the Tokay Gecko are disposed at the terminus of each protrusion.

Abstract: A curved surfaces for adhering to contact surfaces is provided. The structure includes a curved surface with a plurality of nano-fibers disposed thereon. When the curved surface is in a first position, at least one of the plurality of nano-fibers contacts the contact surface and provides an adhesive force at the contact surface. When the curved surface rotates to a second position from the first position, the at least one of the plurality of nano-fibers is leveraged way from the contact surface.

Abstract: A method of forming an adhesive force includes removing a seta from a living specimen, attaching the seta to a substrate, and applying the seta to a surface so as to establish an adhesive force between the substrate and the surface. The seta is applied to the surface with a force perpendicular to the surface. The seta is then pulled with a force parallel to the surface so as to preload the adhesive force of the seta.