Provided is a three-dimensional semiconductor device and its fabrication method. The semiconductor device includes a first active region on a substrate and including a plurality of lower channel patterns and a plurality of lower source/drain patterns that are alternately arranged along a first direction, a second active region on the first active region and including a plurality of upper channel patterns and a plurality of upper source/drain patterns that are alternately arranged along the first direction, a first gate electrode on a first lower channel pattern of the lower channel patterns and on a first upper channel pattern of the upper channel patterns, and a second gate electrode on a second lower channel pattern of the lower channel patterns and on a second upper channel pattern of the upper channel patterns. The second gate electrode may include lower and upper gate electrodes with an isolation pattern interposed therebetween.

Technologies are generally described related to three-dimensional integration of integrated circuits (ICs) with spacing for heat dissipation. According to some examples, a self-aligned silicide may be formed in a temporary silicon layer and removed subsequent to bonding of the wafers to achieve improved contact between the combined ICs and enhanced heat dissipation through added spacing between the ICs.

The method for preventing epitaxial growth in a semiconductor device begins with cutting a set of long fins into a set of fins of a FinFET structure. Each of the set of fins has respective cut faces located at the fin ends of a set of fin ends. A photoresist layer is patterned over the set of fin ends on the set of fins of the FinFET structure. The set of fins are isolated from one another by a first dielectric material. The photoresist is patterned over the set of fin ends so that it differs from the photoresist pattern over other areas of the FinFET structure. A set of dielectric blocks is formed on the set of fin ends using the photoresist pattern. The set of dielectric blocks prevents epitaxial growth at the set of fin ends in a subsequent epitaxial growth step.

A transistor whose channel is formed in a semiconductor having dielectric anisotropy is provided. A transistor having a small subthreshold swing value is provided. A transistor having normally-off electrical characteristics is provided. A transistor having a low leakage current in an off state is provided. A semiconductor device includes an insulator, a semiconductor, and a conductor. In the semiconductor device, the semiconductor includes a region overlapping with the conductor with the insulator positioned therebetween, and a dielectric constant of the region in a direction perpendicular to a top surface of the region is higher than a dielectric constant of the region in a direction parallel to the top surface.

A method comprises providing a first substrate having dielectric structures and conductive structures. Ions are implanted into the first substrate, the ions traveling through the dielectric structures and the conductive structures to define a cleave plane in the first substrate. The first substrate is cleaved at the cleave plane to obtain a cleaved layer having the dielectric structure and the conductive structures. The cleaved layer is used to form a three-dimensional integrated circuit device having a plurality of stacked integrated circuit (IC) layers, the cleaved layer being one of the stacked IC layers.

This method comprises the following steps: a) providing a first structure successively comprising a first substrate, a first electronic device, and a first dielectric layer; a second structure successively comprising a second substrate, an active layer, a second dielectric layer, and a polycrystalline semiconductor layer, the active layer being designed to form a second electronic device; b) bombarding the polycrystalline semiconductor layer by a beam of species configured to form an amorphous part and to preserve a superficial polycrystalline part; c) bonding the first and second structures; d) removing the second substrate of the second structure; e) introducing dopants into the amorphous part, through the exposed active layer; f) thermally activating the dopants by recrystallization of the amorphous part.

Monolithic 3D ICs employing one or more local inter-level interconnect integrated intimately with at least one structure of at least one transistor on at least one transistor level within the 3D IC. In certain embodiments the local inter-level interconnect intersects a gate electrode or a source/drain region of at least one transistor and extends through at least one inter-level dielectric layer disposed between a first and second transistor level in the 3D IC. Local inter-level interconnects may advantageously make a direct vertical connection between transistors in different levels of the 3D IC without being routed laterally around the footprint (i.e., lateral, or planar, area) of either the overlying or underlying transistor level that is interconnected.

Variable handle wafer resistivity for silicon-on-insulator devices. In some embodiments, a radio-frequency device can include a silicon-on-insulator substrate having an insulator layer and a handle wafer. The radio-frequency device can further include a plurality of field-effect transistors implemented over the insulator layer to cover a corresponding portion of the handle wafer having a non-uniform distribution of resistivity values.

This method includes the following steps: a) providing a first structure successively including a substrate, an electronic device, a dielectric layer, and a first semiconductor layer; b) providing a second structure successively including a substrate, an active layer, a dielectric layer, and a second semiconductor layer, the active layer being designed to form an electronic device; c) bonding the first and second structures by direct bonding between the first and second semiconductor layers so as to form a bonding interface; d) removing the substrate of the second structure so as to expose the active layer; e) introducing dopants into the first and second semiconductor layers so as to form a ground plane.

An object is to provide a semiconductor device with a novel structure. The semiconductor device includes a first wiring; a second wiring; a third wiring; a fourth wiring; a first transistor having a first gate electrode, a first source electrode, and a first drain electrode; and a second transistor having a second gate electrode, a second source electrode, and a second drain electrode. The first transistor is provided in a substrate including a semiconductor material. The second transistor includes an oxide semiconductor layer.