A semiconductor device includes: a first semiconductor layer of first conductivity type; a second semiconductor layer of first conductivity type provided on the first semiconductor layer; a first semiconductor region of second conductivity type provided on the second semiconductor layer; a second semiconductor region of first conductivity type provided on the first semiconductor region; a first electrode provided in a first trench, the first trench reaching the second semiconductor layer from above the first semiconductor region, the first electrode facing the first semiconductor region via a first insulating film; a second electrode provided in a second trench, the second trench reaching the second semiconductor layer from above the first semiconductor region, the second electrode facing the first semiconductor region via a second insulating film; a third electrode including a first electrode portion, a second electrode portion provided on the first electrode portion and a third electrode portion provided on the second electrode portion, the first electrode portion being provided between the first trench and the second trench, the first electrode portion reaching the first semiconductor region from above the second semiconductor region, the first electrode portion being electrically connected to the first semiconductor region and the second semiconductor region; a third semiconductor region provided between the third electrode and the second semiconductor region provided between the first insulating film and the third electrode, the third semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region; a fourth semiconductor region provided between the third electrode and the second semiconductor region provided between the second insulating film and the third electrode, the fourth semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region; and a fifth semiconductor region provided between the first semiconductor region and the third electrode, the fifth semiconductor region being provided apart from the third semiconductor region and the fourth semiconductor region, the fifth semiconductor region having a higher concentration of impurities of second conductivity type than the first semiconductor region.

A self-aligned p+ contact MOSFET device is provided. A process to manufacture the device includes forming oxide plugs on top of gate trenches, conducting uniform silicon mesa etch back, and forming oxide spacers to form contact trenches.

A semiconductor device includes a semiconductor layer that has a first main surface at one side and a second main surface at another side, a first main surface electrode that includes a first electrode covering the first main surface and a second electrode having a higher hardness than the first electrode and covering the first electrode, and an oxide layer that covers the first main surface electrode.

A memory device includes a first stacking structure, a second stacking structure, a plurality of first isolation structures, gate dielectric layers, channel layers and channel layers. The first stacking structure includes a plurality of first gate layers, and a second stacking structure includes a plurality of second gate layers, where the first stacking structure and the second stacking structure are located on a substrate and separated from each other through a trench. The first isolation structures are located in the trench, where a plurality of cell regions are respectively confined between two adjacent first isolation structures of the first isolation structures in the trench, where the first isolation structures each includes a first main layer and a first liner surrounding the first main layer, where the first liner separates the first main layer from the first stacking structure and the second stacking structure. The gate dielectric layers are respectively located in one of the cell regions, and cover opposing sidewalls of the first stacking structure and the second stacking structure as well as opposing sidewalls of the first isolation structures. The channel layers respectively cover an inner surface of one of the gate dielectric layers. The conductive pillars stand on the substrate within the cell regions, and are laterally surrounded by the channel layers, where at least two of the conductive pillars are located in each of the cell regions, and the at least two conductive pillars in each of the cell regions are laterally separated from one another.

A semiconductor device includes a first transistor, a second transistor, a third electrode, and a control layer. The first transistor includes a first region of a semiconductor layer, a first electrode, and a first gate electrode, The first electrode is electrically connected with the first region. The first gate electrode is located in the first region. The second transistor includes a second region of the semiconductor layer, a second gate electrode, and a second electrode. The second region is next to the first region. The second gate electrode is located in the second region. The second electrode is electrically connected with the second region. The third electrode is electrically connected with the first and second transistors. The control layer has a smaller linear expansion coefficient than the third electrode.

A semiconductor device includes transistor cells formed along a first surface at a front side of a semiconductor body and having body regions of a first conductivity type, a drift region of a second conductivity type that is opposite from the first conductivity type and is disposed between the body regions and a second surface of the semiconductor body that is opposite from the first surface, and an emitter layer of the second conductivity type that is disposed between the drift region and a second surface of the semiconductor body, the emitter layer having a higher dopant concentration than the drift region, a metal drain electrode directly adjoining the emitter layer. The metal drain electrode comprises spikes extending into the emitter layer.

A modular concept for Silicon Carbide power devices is disclosed where a low voltage module (LVM) is designed separately from a high voltage module (HVM). The LVM having a repeating structure in at least a first direction, the repeating structure repeats with a regular distance in at least the first direction, the HVM comprising a buried grid (4) with a repeating structure in at least a second direction, the repeating structure repeats with a regular distance in at least the second direction, along any possible defined direction. Advantages include faster easier design and manufacture at a lower cost.

To improve reliability of a semiconductor device. There are provided the semiconductor device and a method of manufacturing the same, the semiconductor including a pad electrode that is formed over a semiconductor substrate and includes a first conductive film and a second conductive film formed over the first conductive film, and a plating film that is formed over the second conductive film and used to be coupled to an external connection terminal (TR). The first conductive film and the second conductive film contains mainly aluminum. The crystal surface on the surface of the first conductive film is different from the crystal surface on the surface of the second conductive film.

A semiconductor structure including a bottom source drain region arranged on a substrate; a semiconductor channel region extending vertically upwards from a top surface of the bottom source drain region; a metal gate disposed around the semiconductor channel region; a top source drain region above the semiconductor channel region; and a top contact partially embedded into the top source drain region.

A device is disclosed. The device includes a first epitaxial region, a second epitaxial region, a first gate region between the first epitaxial region and a second epitaxial region, a first dielectric structure underneath the first epitaxial region, a second dielectric structure underneath the second epitaxial region, a third epitaxial region underneath the first epitaxial region, a fourth epitaxial region underneath the second epitaxial region, and a second gate region between the third epitaxial region and a fourth epitaxial region and below the first gate region. The device also includes, a conductor via extending from the first epitaxial region, through the first dielectric structure and the third epitaxial region, the conductor via narrower at an end of the conductor via that contacts the first epitaxial region than at an opposite end.