A microstructured substrate includes a plurality of at least one elementary microstructure. An electrical storage device, and more particularly an all-solid-state battery, can include the microstructured substrate.

The present invention relates to an easy, scalable method, relying on conventional and unconventional techniques, to incorporate tilt in the fabrication of synthetic polymer-based dry adhesives mimicking the gecko adhesive system. These dry, reversible adhesives demonstrate anisotropic adhesion properties, providing strong adhesion and friction forces when actuated in the gripping direction and an initial repulsive normal force and negligible friction when actuated in the releasing direction.

In an embodiment, an article having an impact textured surface comprises a plurality of vertical pillars; and a plurality of annular impact features; wherein a first portion of the vertical pillars is located in an annulus of the plurality of annular impact features and a second portion of the vertical pillars is located in an area around the plurality of annular impact features; wherein a height of the plurality of annular impact features is at least 10 nanometers greater than a height of the plurality of vertical pillars. In another embodiment, a method of making the article comprises molding the impact textured surface from a mold comprising a plurality of holes and a plurality of annular track features; wherein the plurality of holes corresponds to the plurality of pillars and the plurality of annular track features corresponds to the plurality of annular impact features.

A microfluidic device, including a controllable shape-changing micropillar where a shape of the shape-changing micropillar is changed by a fluid.

A microfluidic device, including a matrix array of controllable shape-changing micropillars where a shape of the shape-changing micropillars is changed by a fluid.

A method of forming a semiconductor structure includes forming a substrate, forming an anchor layer, and forming one or more self-aligned nanotip pillar pairs disposed vertically between the substrate and the anchor layer. A given one of the nanotip pillar pairs comprises a bottom nanotip pillar and a top nanotip pillar, the bottom nanotip pillar comprising a base portion disposed on a top surface of the substrate and the top nanotip pillar comprising a base portion disposed in the anchor layer. The bottom nanotip pillar and the top nanotip pillar comprise sidewalls that taper to points as distance from the respective base portions increases.

A structure for a MEMS device includes a MEMS layer comprising a mass portion and a spring portion, a substrate coupled to the MEMS layer, wherein the substrate comprises a planar region and an stopper region, wherein the MEMS device and the substrate are oriented in a plurality of relative orientations in response to an external force, wherein the spring portion and the stopper region are configured to disengagingly impact when the external force exceeds a first threshold force, wherein the mass portion and the planar region are configured to disengagingly impact when the external force exceeds a second threshold force, and wherein the second threshold force exceeds the first threshold force.

A microelectromechanical system (MEMS) sensor assembly comprises a substrate, a bump stopper extending from the substrate, and a sensor suspended relative to the substrate. The sensor is configured to move relative to the substrate, wherein the bump stopper is configured to restrain the sensor travel distance and prevent contact between the sensor and the substrate. The bump stopper has a surface facing the sensor, wherein an area of contact between the sensor and the surface is less than the total area of the surface.

A substrate for sensing, a method of manufacturing the substrate, and an analyzing apparatus including the substrate are provided. The substrate for sensing includes: a support layer; a plurality of metal nanoparticle clusters arranged on the support layer; and a plurality of perforations arranged among the plurality of metal nanoparticle clusters. The plurality of metal nanoparticle clusters each comprise a plurality of metal nanoparticles stacked in a three-dimensional structure. Each of the plurality of perforations transmits incident light therethrough.

A system and method for manufacturing a micropillar array (20). A carrier (11) is provided with a layer of metal ink (20i). A high energy light source (14) irradiates the metal ink (20i) via a mask (13) between the carrier (11) and the light source. The mask is configured to pass a cross-section illuminated image of the micropillar array onto the metal ink (20i), thereby causing a patterned sintering of the metal ink (20i) to form a first subsection layer (21) of the micropillar array (20) in the layer of metal ink (20i). A further layer of the metal ink (20i) is applied on top of the first subsection layer (21) of the micropillar array (20) and irradiated via the mask (13) to form a second subsection layer (21) of the micropillar array on top. The process is repeated to achieve high aspect ratio micropillars 20p.