A system is provided. The system includes a 3D printer, which includes a first dispenser and a second dispenser. The first dispenser is configured to apply conductive material to a surface, and the second dispenser is configured to apply conductive diamonds to a surface. The conductive material includes a mixture of an elastomer and at least one of nickel and silver, and the conductive diamonds are between 1 and 10 microns in size.

A method of forming a pattern of metallic material on a substrate includes providing a plurality of void regions on a surface of the substrate. At a first temperature, a first layer of a first metallic material of a eutectic-forming pair of metallic materials is deposited on the substrate to form a conformal metallic film over the substrate and over the surfaces of the plurality of void regions. The substrate and conformal metallic film are warmed to a second temperature greater than a eutectic-liquid-formation temperature of the eutectic pair of metallic materials. At the second temperature, the second metallic material of the eutectic-forming pair of metallic materials is deposited on the conformal metallic film to initiate a eutectic-liquid-forming reaction, such that the plurality of void regions are filled with a mixture of the first and second metallic materials of the eutectic-forming pair of metallic materials.

Aspects of the present technology are directed toward Integrated Circuits (IC) including a plurality of trenches disposed in a substrate about a set of silicide regions. The trenches can extend down into the substrate below the set of silicide regions. The silicide regions can be formed by implanting metal ions into portions of a substrate exposed by a mask layer with narrow pitch openings. The trenches can be formed by selectively etching the substrate utilizing the set of silicide regions as a trench mask. An semiconductor material with various degree of crystallinity can be grown from the silicide regions, in openings that extend through subsequently formed layers down to the silicide regions.

A capacitive microelectromechanical device is provided. The capacitive microelectromechanical device includes a semiconductor substrate, a support structure, an electrode element, a spring element, and a seismic mass. The support structure, for example, a pole, suspension or a post, is fixedly connected to the semiconductor substrate, which may comprise silicon. The electrode element is fixedly connected to the support structure. Moreover, the seismic mass is connected over the spring element to the support structure so that the seismic mass is displaceable, deflectable or movable with respect to the electrode element. Moreover, the seismic mass and the electrode element form a capacitor having a capacitance which depends on a displacement between the seismic mass and the electrode element.

A method is provided. The method includes preparing a surface to receive a 3D printed layer, 3D printing a conductive layer comprising a plurality of overlaid layers of conductive material to the surface, and 3D printing conductive diamonds to the conductive layer. Preparing the surface includes one or more of texturing the surface and chemically treating the surface. The texturing is performed in order to not adversely impact regularity of the surface and limit variations in the height from the surface of conductive diamonds. Chemically treating the surface reduces films or coatings that may impact adhesion between the surface and the conductive layer, without degrading the conductive layer.

The present invention provides a non-volatile memory and a manufacturing method for the same. In the non-volatile memory, a floating gate structure has a first sharp portion and a second sharp portion, and a corner formed by a side surface of the floating gate structure and a part of a top surface of the floating gate structure is not covered by a control gate structure. The corner is connected between the first sharp portion and one end of the second sharp portion. A tunneling dielectric layer of an erasing gate structure covers the first sharp portion, the second sharp portion, and a tip part of the corner.

A method is provided of forming a superconductor device interconnect structure. The method comprises forming a first dielectric layer overlying a substrate and forming a superconducting interconnect element in the first dielectric layer. The superconducting interconnect element includes a top surface aligned with a top surface of the first dielectric layer to form a first interconnect layer. The superconductor device interconnect structure is moved into a dielectric deposition chamber. The method further comprises performing a cleaning process on a top surface of the first interconnect layer in the dielectric deposition chamber to remove oxidization from a top surface of the first interconnect layer, and depositing a second dielectric layer over the first interconnect layer in the dielectric deposition chamber.

Provided herein is a method for manufacturing a semiconductor device. The method may include: forming a stack including at least one first material layer and at least one second material layer which are alternately stacked; forming first holes through which the at least one first material layer is exposed; forming etch stop patterns in the respective first holes; forming at least one slit passing through the stack; replacing the at least one first material layer with at least one third material layer through the at least one slit; and forming first contact plugs in the respective first holes, the first contact plugs passing through the etch stop patterns and coupled with the at least one third material layer.

A resistive material is formed straddling over each semiconductor fin that extends upward from a surface of a substrate. The resistive material is then disconnected by removing the resistive material from atop each semiconductor fin. Remaining resistive material in the form of a U-shaped resistive material liner is present between each semiconductor fin. Contact structures are formed perpendicular to each semiconductor fin and contacting a portion of a first set of the semiconductor fins and a first set of the U-shaped resistive material liners.

A mirror substrate includes a transparent substrate, a plurality of first mirror patterns arranged on the transparent substrate and spaced apart from each other, each of the first mirror patterns including a phase compensation layer and a first mirror layer sequentially stacked on the transparent substrate, and a second mirror layer disposed on the transparent substrate and between neighboring ones of the first mirror patterns, the second mirror layer having a second thickness less than a first thickness of the first mirror layer.