An integrated circuit (IC) with an impedance sensor fabricated on a surface of the substrate is disclosed. The impedance sensor includes a bottom conductive plate formed on the substrate. A sensing membrane is formed on the bottom conductive plate. A top conductive plate is formed on the sensing membrane, in which the top conductive plate is a fusion of conductive nanoparticles having a random three dimensional porosity that is permeable to a reagent.

A gate unit and a manufacturing method thereof, a method of manufacturing an array substrate, and a display mechanism are provided. The method of manufacturing a gate unit includes: providing a conductive layer on a substrate; forming a photoresist layer on a side of the conductive layer away from the substrate; exposing the photoresist layer, and then developing the photoresist layer to form a groove extending through the photoresist layer on the photoresist layer, so as to form the photoresist layer with a pattern; and electrochemically depositing a functional material on the photoresist layer with the pattern, and then removing the photoresist layer to obtain the conductive layer having a pattern layer formed thereon, so as to obtain the gate unit.

Provided is a plating apparatus for plating a substrate by using a substrate holder including an elastic projection that seals a to-be-plated surface of the substrate, the plating apparatus comprising a measurement device configured to measure a deformed state of the elastic projection by measuring at least either one of a compression amount of the elastic projection and load applied to the elastic projection at a time when the substrate physically contacts the elastic projection of the substrate holder; and a controlling device configured to make a judgment on the basis of the measured deformed state as to whether sealing by the elastic projection is normal.

A plating method can improve adhesivity with a substrate. The plating method of performing a plating process on the substrate includes forming a vacuum-deposited layer 2A on the substrate 2 by performing a vacuum deposition process on the substrate 2; forming an adhesion layer 21 and a catalyst adsorption layer 22 on the vacuum-deposited layer 2A of the substrate 2; and forming a plating layer stacked body 23 having a first plating layer 23a and a second plating layer 23b which function as a barrier film on the catalyst adsorption layer 22 of the substrate 2. By forming the vacuum-deposited layer 2A, a surface of the substrate 2 can be smoothened, so that the vacuum-deposited layer 2A serving as an underlying layer can improve the adhesivity.

A plating method can improve adhesivity with a substrate. The plating method of performing a plating process on the substrate includes forming a vacuum-deposited layer 2A on the substrate 2 by performing a vacuum deposition process on the substrate 2; forming an adhesion layer 21 and a catalyst adsorption layer 22 on the vacuum-deposited layer 2A of the substrate 2; and forming a plating layer stacked body 23 having a first plating layer 23a and a second plating layer 23b which function as a barrier film on the catalyst adsorption layer 22 of the substrate 2. By forming the vacuum-deposited layer 2A, a surface of the substrate 2 can be smoothened, so that the vacuum-deposited layer 2A serving as an underlying layer can improve the adhesivity.

A semiconductor device package that incorporates a combination of ceramic, organic, and metallic materials that are coupled using silver is provided. The silver is applied in the form of fine particles under pressure and a low temperature. After application, the silver forms a solid that has a typical melting point of silver, and therefore the finished package can withstand temperatures significantly higher than the manufacturing temperature. Further, since the silver is an interfacial material between the various combined materials, the effect of differing material properties between ceramic, organic, and metallic components, such as coefficient of thermal expansion, is reduced due to low temperature of bonding and the ductility of the silver.

A semiconductor device package that incorporates a combination of ceramic, organic, and metallic materials that are coupled using silver is provided. The silver is applied in the form of fine particles under pressure and a low temperature. After application, the silver forms a solid that has a typical melting point of silver, and therefore the finished package can withstand temperatures significantly higher than the manufacturing temperature. Further, since the silver is an interfacial material between the various combined materials, the effect of differing material properties between ceramic, organic, and metallic components, such as coefficient of thermal expansion, is reduced due to low temperature of bonding and the ductility of the silver.

An interconnect for electrically coupling pads formed on adjacent chips or on packaging material adjacent the chips, with an electrically conductive heat sink being disposed between the pads, the interconnect comprising a metallic membrane layer disposed between two adjacent pads and disposed or bridging over the electrically conductive heat sink so as to avoid making electrical contact with the electrically conductive heat sink. An electroplated metallic layer is disposed on the metallic membrane layer. Fabrication of interconnect permits multiple interconnects to be formed in parallel using fabrication techniques compatible with wafer level fabrication of the interconnects. The interconnects preferably follow a smooth curve to electrically connect adjacent pads and following that smooth curve they bridge over the intervening electrically conductive heat sink material in a predictable fashion.

Atomic layer etching (ALE) enables effective filling of small feature structures on semiconductor and other substrates, such as contacts and vias, by bottom-up fill, for example electroless deposition (ELD) of cobalt.

A method providing a high aspect ratio through substrate via in a substrate is described. The through substrate via has vertical sidewalls and a horizontal bottom. The substrate has a horizontal field area surrounding the through substrate via. A metallic barrier layer is deposited on the sidewalls of the through substrate via. A nitridation process converts a surface portion of the metallic barrier layer to a nitride surface layer. The nitride surface layer enhances the nucleation of subsequent depositions. A first metal layer is deposited to fill a portion of the through substrate via and cover the horizontal field area. A thermal anneal step to reflow a portion of the first metal layer on the horizontal field area into the through substrate via. A second metal layer is deposited over the first metal layer to fill a remaining portion of the through substrate via. Another aspect of the invention is a device created by the method.