A first electrode of a MEMS device can be oriented lengthwise along and parallel to an axis, and can have a first end and a second end. A second electrode can be oriented lengthwise along and parallel to the axis and can have a first end and a second end. A third electrode can be oriented lengthwise along and parallel to the axis and can have a first end and a second end. The first, second, and third electrodes can each be located at least partially within an aperture of a plurality of apertures of a solid dielectric that can surround the second electrode second end and the third electrode first end. The second electrode first end and the third electrode second end can be located outside of the solid dielectric.

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 invention relates to a method for manufacturing structural layers for guiding liquid flow on a porous substrate, by printing onto at least one area of at least one surface of the substrate a printing solution containing an aqueous dispersion of a poly(lactic acid)-based copolymer.

A MEMS device can include a solid dielectric including a plurality of apertures, the solid dielectric having a first side and a second side. The MEMS device can include a first plurality of electrodes extending completely through a first subset of the plurality of apertures, a second plurality of electrodes extending partially through a second subset of the plurality of apertures, a third plurality of electrodes extending partially into a third subset of the plurality of apertures. The MEMS device can include a first diaphragm coupled to the first plurality and to the third plurality of electrodes, the first diaphragm facing the first side of the solid dielectric. The MEMS device can include a second diaphragm coupled to the first plurality and to the second plurality of electrodes the second diaphragm facing the second side of the solid dielectric.

A microfabricated pressure transducer is formed in a multilayer substrate by etching a plurality of shallow and deep wells into the layers, and then joining these wells with voids formed by anisotropic etching. The voids define a flexible membrane over the substrate which deforms when a force is applied.

A master tool is provided with an ink pattern on a major surface thereof. The ink pattern is formed by a screen printing process. A stamp-making material is applied to the major surface of the master tool to form a stamp having a stamping pattern being negative to the ink pattern of the master tool. The stamping pattern is inked with an ink composition and contacted with a metalized surface to form a printed pattern on a metalized surface of a substrate according to the stamping pattern. Using the printed pattern as an etching mask, the metalized surface is etched to form electrically conductive traces on the substrate.

A first electrode of a MEMS device can be oriented lengthwise along and parallel to an axis, and can have a first end and a second end. A second electrode can be oriented lengthwise along and parallel to the axis and can have a first end and a second end. A third electrode can be oriented lengthwise along and parallel to the axis and can have a first end and a second end. The first, second, and third electrodes can each be located at least partially within an aperture of a plurality of apertures of a solid dielectric that can surround the second electrode second end and the third electrode first end. The second electrode first end and the third electrode second end can be located outside of the solid dielectric.

A MEMS device can include a solid dielectric including a plurality of apertures, the solid dielectric having a first side and a second side. The MEMS device can include a first plurality of electrodes extending completely through a first subset of the plurality of apertures, a second plurality of electrodes extending partially through a second subset of the plurality of apertures, a third plurality of electrodes extending partially into a third subset of the plurality of apertures. The MEMS device can include a first diaphragm coupled to the first plurality and to the third plurality of electrodes, the first diaphragm facing the first side of the solid dielectric. The MEMS device can include a second diaphragm coupled to the first plurality and to the second plurality of electrodes the second diaphragm facing the second side of the solid dielectric.

The present invention provides an infrared detector pixel structure and manufacturing method thereof. The structure comprises a conductive metal region on surface of the silicon substrate; an infrared detecting element located above the silicon substrate for detecting infrared light and generating electrical signal; and a conductive beam unit electrically connected to the infrared detecting element for transmitting the electrical signal to the conductive metal region; the conductive beam unit includes at least one conductive beam layer and multilayer conductive trench arranged in a vertical direction; two ends of the conductive beam are respectively in contact with two layers of conductive trenches whose bottom portions are not in the same horizontal plane; the infrared detecting element is in contact with one conductive trench one conductive beam; the conductive metal region is in contact with bottom portion of the other layer of conductive trench therein; the electrical signal is transmitted along the height direction of the conductive trench and the conductive beam, so as to be transmitted downward to the conductive metal region in a circuitous path in the vertical direction.

The present invention relates to a method for manufacturing structural layers for guiding liquid flow on a porous substrate, by printing onto at least one area of at least one surface of the substrate a printing solution containing an aqueous dispersion of a poly(lactic acid)-based copolymer.