Various three-dimensional devices that can be formed within the bulk of a semiconductor by photo-controlled selective etching are described herein. With more particularity, semiconductor devices that incorporate three-dimensional electrical vias, waveguides, or fluidic channels that are disposed within a semiconductor are described herein. In an exemplary embodiment, a three-dimensional interposer chip includes an electrical via, a waveguide, and a fluidic channel, wherein the via, the waveguide, and the fluidic channel are disposed within the body of a semiconductor element rather than being deposited on a surface. The three-dimensional interposer is usable to make electrical, optical, or fluidic connections between two or more devices.

An optical electronics device includes first, second and third wafers. The first wafer has a semiconductor substrate with a dielectric layer on a side of the semiconductor substrate. The second wafer has a transparent substrate with an anti-reflective coating on a side of the transparent substrate. The first wafer is bonded to the second wafer at a silicon dioxide layer between the semiconductor substrate and the anti-reflective coating. The first and second wafers include a cavity extending from the dielectric layer through the semiconductor substrate and through the silicon dioxide layer to the anti-reflective coating. The third wafer includes micromechanical elements. The third wafer is bonded to the dielectric layer, and the micromechanical elements are contained within the cavity.

Custom 3d printer and resin for microfluidic flow channels and 3D printed high density, reversible, chip-to-chip microfluidic interconnects.

A microfluidic device, a diagnostic device including the microfluidic device and a method for making the microfluidic device are provided. The microfluidic device includes: (i) a transparent substrate comprising a cavity, the cavity opening up to a top of the transparent substrate; (ii) a transparent layer covering the cavity, and (iii) a semiconductor substrate over the transparent layer and the transparent substrate, wherein the semiconductor substrate comprises a through hole overlaying the cavity and exposing the transparent layer.

A MEMS device and a method of forming the same. A disclosed method includes: providing a silicon substrate layer, a buried oxide layer and a device silicon layer; using a microfabrication process to pattern a set of device features on the device silicon layer including a shuttle mass and an anchor frame; removing the silicon substrate layer and buried oxide below the shuttle mass; placing a shadow mask on a surface of the device silicon layer, wherein the shadow mask has an microscale opening to expose at least one device feature; and forming a nanoscale stopper on a sidewall of the at least one device feature by depositing a deposition material through the opening in a controlled manner.

A method for manufacturing a flow path device internally provided with a flow path for allowing a liquid to flow by compression bonding two or more members to each other, in which the hydrophilic property of a surface of the flow path can be maintained for a long period of time. A flow path device is manufactured by forming a hydrophilic coating film using a treatment liquid including a hydrophilizing agent in at least one member, the coating film covering a surface of the member at a side to be joined to another member, then irradiating only a joining surface of the coating film with ultraviolet rays or plasma derived from an oxygen-containing gas in the member having the coating film, and irradiating at least the joining surface with ultraviolet rays or plasma derived from an oxygen-containing gas in a member having no coating film, and compression bonding the two or more members.

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 manufacturing method of micro channel structure is disclosed and includes steps of: providing a substrate; depositing and etching to form a first insulation layer; depositing and etching to form a supporting layer; depositing and etching to form a valve layer; depositing and etching to form a second insulation layer; depositing and etching to form a vibration layer, a lower electrode layer and a piezoelectric actuating layer; providing a photoresist layer and depositing and etching to form a plurality of bonding pads; depositing and etching to from a mask layer; etching to form a first chamber; and etching to form a second chamber.

A method of etching features in a silicon wafer includes coating a top surface and a bottom surface of the silicon wafer with a mask layer having a lower etch rate than an etch rate of the silicon wafer, removing one or more portions of the mask layer to form a mask pattern in the mask layer on the top surface and the bottom surface of the silicon wafer, etching one or more top surface features into the top surface of the silicon wafer through the mask pattern to a depth plane located between the top surface and the bottom surface of the silicon wafer at a depth from the top surface, coating the top surface and the one or more top surface features with a metallic coating, and etching one or more bottom surface features into the bottom surface of the silicon wafer through the mask pattern to the target depth plane.

A method for producing a micromechanical component having a substrate and a cap that are connected to each other and that enclose a first cavity, where a first pressure prevails inside the first cavity and a first gas mixture having a first chemical composition is enclosed within the first cavity, includes, in a first method step, developing in the substrate or cap an access opening connecting the first cavity to an environment of the micromechanical component, in a second method step, setting the first pressure and/or the first chemical composition in the first cavity, in a third method step, sealing the access opening using a laser by introduction of energy or heat into an absorbing part of the substrate or the cap, and, in a fourth method step, performing a thermal treatment of the substrate or the cap, thereby reducing temperature gradients in the substrate or in the cap.