This disclosure is related to integrating pixelated microdevices into a system substrate to develop a functional system such as display, sensors, and other optoelectronic devices. The process may involve having a structure of release layers in the housing and then using different decoupling mechanisms for release. The release layers are not limited to but can be a combination of chemical or optical or mechanical release layers.

A method for functionalizing a surface of a dielectric plate that is transparent to visible light—to be able to examine the dielectric plate using optical microscopy—includes depositing a negative film on the dielectric slide. The negative film comprises a polymerizable composition that polymerizes when exposed to an electron beam. The polymerizable composition is polymerized—by exposing the negative film to the electronic beam—at a set of points representing a preset pattern. Non-polymerized portions of the polymerizable composition are dissolved—to develop the negative film—forming a set of pads of polymerized portions of the polymerizable composition. Each pad corresponds to one point of the preset pattern. A metal film is disposed on the negative film, and the developed negative film is dissolved to define holes through the metal film. Each of the holes corresponds to a base of one pad of the set of pads.

An ultrasonic transducer includes a membrane, a bottom electrode, and a plurality of cavities disposed between the membrane and the bottom electrode, each of the plurality of cavities corresponding to an individual transducer cell. Portions of the bottom electrode corresponding to each individual transducer cell are electrically isolated from one another. Each portion of the bottom electrode corresponds to each individual transducer that cell further includes a first bottom electrode portion and a second bottom electrode portion, the first and second bottom electrode portions electrically isolated from one another.

Various embodiments of the present disclosure are directed towards a microelectromechanical systems (MEMS) device in which a slit at a movable mass of the MEMS device has a top notch slit profile. The MEMS device may, for example, be a speaker, an actuator, or the like. The slit extends through the movable mass, from top to bottom, and has a width that is uniform, or substantially uniform, from the bottom of the movable mass to proximate the top of movable mass. Further, in accordance with the top notch slit profile, top corner portions of the MEMS substrate in the slit are notched, such that a width of the slit bulges at the top of the movable mass. The top notch slit profile may, for example, increase the process window for removing an adhesive from the slit while forming the MEMS device.

A resonator includes an anchor, an outer stiffener ring on an outer perimeter of the resonator, and a plurality of curved springs between the anchor and the outer stiffener ring.

A method for forming a nanostructure includes coating an exposed surface of a base layer with a patterning layer. The method further includes forming a pattern in the patterning layer including nano-patterned non-random openings, such that a bottom portion of the non-random openings provides direct access to the exposed surface of the base layer. The method also includes depositing a material in the non-random openings in the patterning layer, such that the material contacts the exposed surface to produce repeating individually articulated nano-scale features. The method includes removing remaining portions of the patterning layer. The method further includes forming an encapsulation layer on exposed surfaces of the repeating individually articulated nanoscale features and the exposed surface of the base layer.

The present disclosure provides a method for the surface modification of microstructured components having a polar surface, in particular for high-pressure applications. According to the method, a microstructured component is contacted, in particular treated, with a modification reagent, wherein the surface properties of the component are modified by chemical and/or physical interaction of the component surface and of the modification reagent.

The present disclosure provides a method for the surface modification of microstructured components having a polar surface, in particular for high-pressure applications. According to the method, a microstructured component is contacted, in particular treated, with a modification reagent, wherein the surface properties of the component are modified by chemical and/or physical interaction of the component surface and of the modification reagent.

Function fabrication in a microfluidic device manufactured with a custom 3D printer. The functions may include, for example, transporting or routing fluid, fluid mixing through flow and/or diffusion, blocking fluid (valve), pumping fluid, providing chemical reaction regions, providing analyte capture regions, and providing analyte separation regions. The fluid may be a liquid or a gas.

Provided is a microfluidic device capable of removing microbubbles in a channel by using a porous thin film, the microfluidic device comprising: an upper panel comprising a microfluidic channel through which a fluid passes; a porous thin film attached to the bottom surface of the microfluidic channel so as to remove microbubbles included in the fluid that passes through the microfluidic channel; a lower panel contacting the bottom surface of the porous thin film and the upper panel, a path being provided in the lower panel so as to discharge microbubbles, which pass through the porous thin film, to the outside; and a vacuum-suctioning means for vacuum-suctioning the upper panel and the lower panel such that the microfluidic channel, to which the porous thin film is attached, is attached to the lower panel in a vacuum state.