A method for producing a pneumatically actuatable microfluidic analysis cartridge includes closing a joining side of a fluidic part of the analysis cartridge with a first fluid-tight elastic membrane and/or closing a joining side of a pneumatic part of the analysis cartridge with a second membrane. The fluidic part is configured to perform fluidic basic operations of a biochemical analysis process, and the pneumatic part is configured to control the basic operations using air pressure. The joining side of the fluidic part and the joining side of the pneumatic part are aligned, and the fluidic part and the pneumatic part are connected to form the analysis cartridge.

A method for bonding wafers eutectically, including the steps: (a) providing a first wafer having a first bonding layer and a second wafer having a second bonding layer and a spacer; (b) bringing the first wafer in juxtaposition with the second wafer, the spacer resting against the first bonding layer; (c) pressing the first wafer and the second wafer together, until the first bonding layer and the second bonding layer abut, the spacer penetrating the first bonding layer; (d) bonding the first wafer to the second wafer eutectically, by forming a eutectic alloy of at least parts of the first bonding layer and the second bonding layer. Also described is a eutectically bonded wafer composite and a micromechanical device having such a eutectically bonded wafer composite.

A method of manufacturing a microfluidic device comprises molding a substrate using a master die having at least one outer stepped formation; and forming at least one microstructured formation having an outer rim, the depth of the outer rim being shallower than that of the microstructured formation.

In an embodiment a method includes providing a coupling element with at least one predefined coupling point, arranging at least one component with a temporary alignment with the predefined coupling point, wherein the component comprises a decoupling point which is approximately aligned with the predefined coupling point of the coupling element, performing an assisted self-alignment of the component with the predefined coupling point, wherein the self-alignment is assisted by utilizing an action of a capillary force on an alignment material which is embedded in the component or attached to the component or by diverting the alignment material, and wherein the decoupling point of the component is moved to the predefined coupling point of the coupling element and adjusted, and permanent fixing of the component to the coupling element after carrying out the assisted self-alignment of the component.

The present disclosure relates to a method for fabricating a micro-electromechanical system (MEMS) device. In the method, a carrier wafer is received. A MEMS wafer, which includes a plurality of die, is bonded to the carrier wafer. A cavity is formed to separate an upper surface of the carrier wafer from a lower surface of a die of the MEMS wafer. A separation trench is formed to laterally surround the die, wherein formation of the cavity and the separation trench leaves a tethering structure suspending the die over the upper surface of the carrier wafer. The die and carrier wafer are translated with respect to one another to break the tethering structure and separate the die from the carrier wafer.

A laser micro-machining process called laser-assisted material phase-change and expulsion (LAMPE) micromachining that includes cutting features in a cutting surface of a piece of material using a pulsed laser with intensity, pulse width and pulse rate set to melt and eject liquid material without vaporizing said material, or, in the case of silicon, create an ejectible silicon oxide. Burrs are removed from the cutting surface by electro-polishing the cutting surface with a dilute acid solution using an electric potential higher than a normal electro-polishing electric potential. A multi-lamina assembly of laser-micro-machined laminates (MALL) may utilize MEMS. In the MALL process, first, the individual layers of a micro-electromechanical system (MEMS) are fabricated using the LAMPE micro-machining process. Next, the fabricated microstructure laminates are stack assembled and bonded to fabricate MEM systems. The MALL MEMS fabrication process enables greater material section and integration, greater design flexibility, low-cost manufacturing, rapid development, and integrated packaging.

The invention includes a method of promoting interfacial mechanical bonding of two or more components through the use of suspended and/or freestanding structures fabricated using an atom-scale assembly process on at least a portion of the surfaces of such components.

A micro-electromechanical pressure transducer formed from a silicon die centers itself on a pedestal, formed from either a metal or a dielectric, by applying a predetermined amount of liquid epoxy adhesive to the square, top surface of the pedestal and allowing the liquid adhesive to distribute itself over the top surface. A MEMS die placed atop the liquid adhesive is centered on the top surface by surface tension between sides of the die and the top surface.

A method includes: providing a first substrate on which a plurality of first semiconductor devices is formed; providing a second substrate on which a plurality of second semiconductor devices is formed; and coupling the first and second substrates by contacting respective dummy pads of the first and second substrates, wherein at least one of the dummy pads of the first and second substrates comprises plural peaks and valleys.

A spatial light modulation element module having a large area is manufactured. A spatial light modulation element module comprising a base member and a plurality of spatial light modulation element arrays, wherein each of the plurality of spatial light modulation element arrays has a light modulation element which modulates and emits at least one of the intensity and the phase of an incident light, and the base member maintains the plurality of spatial light modulation element arrays in a predetermined relative position in a bare chip state. In the above-described spatial light modulation element module, the plurality of spatial light modulation element arrays may be in a staggered arrangement in at least 1 direction.