High-voltage semiconductor devices are provided. The high-voltage semiconductor device includes a substrate and an isolation structure in the substrate. The high-voltage semiconductor device includes a gate structure disposed on the substrate, wherein the gate structure is separated from the isolation structure by a distance. The high-voltage semiconductor device also includes a metal electrode disposed on the gate structure, wherein the metal electrode extends to directly above the isolation structure. The high-voltage semiconductor device further includes an interconnection structure including the lowest metal layer, wherein the metal electrode is between the lowest metal layer and the gate structure. Methods of manufacturing the high-voltage semiconductor device are also provided.

The manufacturing method of a semiconductor device can improve the mechanical strength of a pad more than before, and suppress the occurrence of a crack. The manufacturing method of a semiconductor device includes: forming a first pad constituted by a first metal layer; forming an insulating layer on the first pad; providing an opening portion in the insulating layer by removing the insulating layer on at least a partial region of the first pad; forming a second pad constituted by a second metal layer in the opening portion of the insulating layer so as to have a film thickness that is smaller than the film thickness of the insulating layer; and forming a third pad constituted by a third metal layer on the second pad.

A flexible display and method of manufacturing the same are disclosed. In one aspect, the display includes a flexible substrate having a bending area and a non-bending area and a plurality of metal wirings formed over the flexible substrate in the bending area and the non-bending area. Each of the metal wirings which are formed in the bending area includes a pair of first hard wirings formed over the flexible substrate and a first soft wiring electrically connected to ends of the pair of first hard wirings.

Aspects of the disclosure include methods of treating a substrate to remove one or more of voids, seams, and grain boundaries from interconnects formed on the substrate. The method includes heating the substrate in an environment pressurized at supra-atmospheric pressure. In one example, the substrate may be heated in a hydrogen-containing atmosphere.

A semiconductor device includes: a first substrate on which a first field effect transistor is provided; and a second substrate on which a second field effect transistor of a second conductive type is provided; the first and second substrates being bonded to each other at the substrate faces thereof on which the first and second field transistors are provided, respectively; the first field effect transistor and the second field effect transistor being electrically connected to each other.

A low reflectance film with a second reflectance (50% or lower) lower than a first reflectance is formed between an optical directional coupler and a first-layer wiring with the first reflectance. Thus, even when the first-layer wiring is formed above the optical directional coupler, the influence of the light reflected by the first-layer wiring on the optical signal propagating through the first optical waveguide and the second optical waveguide of the optical directional coupler can be reduced. Accordingly, the first-layer wiring can be arranged above the optical directional coupler, and the restriction on the layout of the first-layer wiring is relaxed.

A semiconductor device includes a first substrate, an insulation layer, and a first electrode. The first substrate contains a first semiconductor material. The insulation layer includes a first surface, a second surface, and a third surface. The first electrode includes a fourth surface, a fifth surface, and a sixth surface, and contains a porous first conductive material. The second surface and the fifth surface configure the same surface. The third surface faces the sixth surface. A distance between the first surface and the first substrate is less than a distance between the second surface and the first substrate. A distance between the fourth surface and the first substrate is less than a distance between the fifth surface and the first substrate.

A wafer including a substrate having a plurality of integrated circuits formed above the substrate, and at least one scribe line between two of the integrated circuits. The wafer further includes a plurality of dielectric layers formed in the at least one scribe line having a process control monitor (PCM) pad structure formed therein, the PCM pad structure having: a plurality of metal pads interconnected by a plurality of conductive vias. The PCM pad further includes a plurality of contact bars in contact with a bottom-most metal pad, the contact bars extending substantially vertically from the bottom-most metal pad into the substrate. Additionally, the PCM pad includes an isolation structure substantially surrounding the plurality of contact bars to isolate the PCM pad structure.

Embodiments of the disclosure relate to methods of depositing tungsten. Some embodiments of the disclosure provide methods for depositing tungsten which are performed at relatively low temperatures. Some embodiments of the disclosure provide methods in which the ratio between reactant gasses is controlled. Some embodiments of the disclosure provide selective deposition of tungsten. Some embodiments of the disclosure provide methods for depositing tungsten films at a low temperature with relatively low roughness, stress and impurity levels.

Methods and apparatus for performing physical vapor deposition in a reactor chamber to form aluminum material on a substrate including: depositing a first aluminum layer atop a substrate to form a first aluminum region having a first grain size and a second aluminum layer atop the first aluminum layer, wherein the second aluminum layer has a second grain size larger than the first grain size; and depositing aluminum atop the second aluminum layer under conditions sufficient to increase the second grain size.