A method to form a 3D integrated circuit, the method including: providing a first wafer including a first crystalline substrate, a plurality of first transistors, and first copper interconnecting layers, where the first copper interconnecting layers at least interconnect the plurality of first transistors; providing a second wafer including a second crystalline substrate, a plurality of second transistors, and second copper interconnecting layers, where the second copper interconnecting layers at least interconnect the plurality of second transistors; and then performing a face-to-face bonding of the second wafer on top of the first wafer, where the face-to-face bonding includes copper to copper bonding; and thinning the second crystalline substrate to a thickness of less than 5 micro-meters.

A charge balance (CB) field-effect transistor (FET) device may include a CB layer defined in a first epitaxial (epi) layer having a first conductivity type. The CB layer may include a set of CB regions having a second conductivity type. The CB FET device may further include a device layer defined in a device epi layer having the first conductivity type disposed on the CB layer. The device layer may include a highly-doped region having the second conductivity type. The CB FET device may also include a CB bus region having the second conductivity type that extends between and electrically couples a CB region of the set of CB regions of the CB layer to the highly-doped region of the device layer.

A semiconductor device includes a substrate; a gate electrode, a source electrode, and a drain electrode, the gate electrode, the source electrode and the drain electrode being formed on the substrate; a plurality of nonconductive nanowires formed two-dimensionally on an upper surface of the substrate so as to extend perpendicularly to the upper surface of the substrate; an electrode pad formed at upper ends of the plurality of nanowires so as to have a gap between the electrode pad and the substrate, the electrode pad being supported by the plurality of nanowires; and an extraction electrode connecting the electrode pad and the gate electrode.

Provided is a semiconductor element including at least, a semiconductor layer including a crystalline oxide semiconductor as a major component; an electrode layer laminated on the semiconductor layer; and a conductive substrate laminated on the electrode layer directly or with another layer in between, the conductive substrate containing at least a first metal selected from the metals in group 11 in the periodic table and a second metal different from the first metal in coefficient of liner thermal expansion.

Semiconductor devices and associated fabrication methods are disclosed. In one disclosed approach a process for forming a semiconductor device is provided. The process includes: implanting a first region of semiconductor material using a first channeled implant with a first conductivity type; and implanting, after the first channeled implant, a second region of semiconductor material using a second channeled implant with a second conductivity type. The first channeled implant disrupts a crystal structure of the first region of semiconductor material and does not disrupt a crystal structure of the second region of semiconductor material.

A nitride semiconductor device includes: a first active area surrounded by an isolation area; and the following electrodes above the first active area: a source electrode; a first gate electrode and a second gate electrode, one on either side of and spaced from the source electrode in a first direction in plan view; and at least one drain electrode located in a direction opposite the source electrode relative to the first gate electrode or the second gate electrode. The source electrode, the first gate electrode, the second gate electrode, and the at least one drain electrode each include a finger-shaped portion extending in a second direction perpendicular to the first direction in the plan view. A first dielectric film is disposed above the source electrode. The first gate electrode and the second gate electrode are electrically connected by a gate electrode joiner disposed above the first dielectric film.

After a nitride semiconductor layer is formed through crystal-growth of a nitride semiconductor containing Ga in a +c-axis direction on the other substrate, the other substrate on which the nitride semiconductor layer is formed is bonded to a substrate in a state where a surface on which the nitride semiconductor layer of the other substrate is formed is on the side of the substrate (a bonding step). This bonding is performed by bonding the surfaces to be bonded by a known direct bonding technology.

A method of manufacturing a vertical metal-semiconductor field-effect transistor (MESFET) device is provided. The method includes forming a first oxide layer, forming a first electrode in the oxide layer, forming a crystallized silicon layer on the first electrode, forming a second electrode on the first oxide layer and on sidewalls of the crystalized silicon layer, forming a second oxide layer on upper surfaces of the second electrode. The method also includes forming a third electrode on an upper surface of the crystallized silicon layer.

A semiconductor device structure includes a region of semiconductor material comprising a first conductivity type, an active region, and a termination region. A first active trench structure is disposed in the active region, and a second active trench structure is disposed in the active region and laterally separated from the first active trench by an active mesa region having a first width. A first termination trench structure is disposed in the termination region and separated from the second active trench by a transition mesa region having a second width and a higher carrier charge than that of the active mesa region. In one example, the second width is greater than the first width to provide the higher carrier charge. In another example, the dopant concentration in the transition mesa region is higher than that in the active mesa region to provide the higher carrier charge. The semiconductor device structure exhibits improved device ruggedness including, for example, improve unclamped inductive switching (UIS) performance.

A 3D device including: a first level including first single crystal transistors overlaid by a second level including second single crystal transistors; a third level including third single crystal transistors, the second level is overlaid by the third level; a fourth level including fourth single crystal transistors, the third level is overlaid by the fourth level; first bond regions including first oxide to oxide bonds, where the first bond regions are between the first level and the second level; second bond regions including second oxide to oxide bonds, where the second bond regions are between the second level and the third level; and third bond regions including third oxide to oxide bonds, where the third bond regions are between the third level and the fourth level, where the second level, third level, and fourth level each include one array of memory cells, and where the one array of memory cells is a DRAM type memory.