Abstract: A method includes forming a fin protruding from a semiconductor substrate; forming a dummy gate stack over the fin, wherein forming the dummy gate stack includes depositing a layer of amorphous material over the fin; performing an anneal process on the layer of amorphous material, wherein the anneal process recrystallizes the layer of amorphous material into a layer of polycrystalline material, wherein the anneal process includes heating the layer of amorphous material for less than one millisecond; and patterning the layer of polycrystalline material; and forming an epitaxial source/drain region in the fin adjacent the dummy gate stack; and removing the dummy gate stack and replacing the dummy gate stack with a replacement gate stack.

Abstract: In an embodiment, a device includes: a first semiconductor fin extending from a substrate; a second semiconductor fin extending from the substrate; a hybrid fin over the substrate, the second semiconductor fin disposed between the first semiconductor fin and the hybrid fin; a first isolation region between the first semiconductor fin and the second semiconductor fin; and a second isolation region between the second semiconductor fin and the hybrid fin, a top surface of the second isolation region disposed further from the substrate than a top surface of the first isolation region.

Abstract: A method includes etching a semiconductor substrate to form a trench and a semiconductor strip. A sidewall of the semiconductor strip is exposed to the trench. The method further includes depositing a silicon-containing layer extending into the trench, wherein the silicon-containing layer extends on the sidewall of the semiconductor strip, filling the trench with a dielectric material, wherein the dielectric material is on a sidewall of the silicon-containing layer, and oxidizing the silicon-containing layer to form a liner. The liner comprises oxidized silicon. The liner and the dielectric material form parts of an isolation region. The isolation region is recessed, so that a portion of the semiconductor strip protrudes higher than a top surface of the isolation region forms a semiconductor fin.

Abstract: In an embodiment, a device includes: a first semiconductor strip over a substrate, the first semiconductor strip including a first channel region; a second semiconductor strip over the substrate, the second semiconductor strip including a second channel region; a dielectric strip disposed between the first semiconductor strip and the second semiconductor strip, a width of the dielectric strip decreasing along a first direction extending away from the substrate, the dielectric strip including a void; and a gate structure extending along the first channel region, along the second channel region, and along a top surface and sidewalls of the dielectric strip.

Abstract: To reduce a thickness variation of a spin-on coating (SOC) layer that is applied over a plurality of first and second trenches with different pattern densities as a bottom layer in a photoresist stack, a two-step thermal treatment process is performed on the SOC layer. A first thermal treatment step in the two-step thermal treatment process is conducted at a first temperature below a cross-linking temperature of the SOC layer to cause flow of the SOC layer, and a second thermal treatment step in the two-step thermal treatment process is conducted at a second temperature to cause cross-linking of the SOC layer.

Abstract: A method for forming a semiconductor structure is provided. The method includes forming a fin structure over a substrate and forming an isolation structure over the substrate. In addition, the fin structure is protruded from the isolation structure. The method further includes trimming the fin structure to a first width and forming a Ge-containing material covering the fin structure. The method further includes annealing the fin structure and the Ge-containing material to form a modified fin structure. The method also includes trimming the modified fin structure to a second width.

Abstract: The present disclosure provides methods of fabricating a semiconductor device. A method according to one embodiment includes forming, on a substrate, a first fin formed of a first semiconductor material and a second fin formed of a second semiconductor material different from the first semiconductor material, forming a semiconductor cap layer over the first fin and the second fin, and annealing the semiconductor cap layer at a first temperature while at least a portion of the semiconductor cap layer is exposed.

Abstract: An antifuse device is disclosed. The antifuse device includes a plurality of active regions, a plurality of word lines extending along a first direction and cut through the active regions, a plurality of bit lines and a plurality of source lines extending along a second direction and stride across the active regions. The bit lines and the source lines are arranged alternatively along the first direction. Plural antifuse capacitors are disposed along the source lines and connected between the source lines and the active regions.

Abstract: A set of test key layout including multiple test keys and method of monitoring layout pattern misalignments using the test keys is provided. Each test key is composed of a testing electrode, an operating voltage (Vdd) line and a grounding voltage (Vss) line, wherein the patterns of test keys are defined by an overlapped portion of a first exposure pattern and a second exposure pattern, and the position of testing electrode is shifted sequentially in one direction in order of the test keys.

Abstract: An antifuse device is disclosed. The antifuse device includes a plurality of active regions, a plurality of word lines extending along a first direction and cut through the active regions, a plurality of bit lines and a plurality of source lines extending along a second direction and stride across the active regions. The bit lines and the source lines are arranged alternatively along the first direction. Plural antifuse capacitors are disposed along the source lines and connected between the source lines and the active regions.

Abstract: A set of test key layout including multiple test keys and method of monitoring layout pattern misalignments using the test keys is provided. Each test key is composed of a testing electrode, an operating voltage (Vdd) line and a grounding voltage (Vss) line, wherein the patterns of test keys are defined by an overlapped portion of a first exposure pattern and a second exposure pattern, and the position of testing electrode is shifted sequentially in one direction in order of the test keys.

Abstract: The memory cell includes a read selection transistor, a program selection transistor, and an anti-fuse capacitor. The read selection transistor has a first terminal coupled to a bit line, a second terminal, and a control terminal coupled to a read word line. The program selection transistor has a first terminal coupled to the second terminal of the read selection transistor, a second terminal coupled to a high voltage control line, and a control terminal coupled to a program word line. The anti-fuse capacitor has a first terminal coupled to the second terminal of the read selection transistor, and a second terminal coupled to a low voltage control line.

Abstract: Some embodiments include methods of forming rutile-type titanium oxide. A monolayer of titanium nitride may be formed. The monolayer of titanium nitride may then be oxidized at a temperature less than or equal to about 550° C. to convert it into a monolayer of rutile-type titanium oxide. Some embodiments include methods of forming capacitors that have rutile-type titanium oxide dielectric, and that have at least one electrode comprising titanium nitride. Some embodiments include thermally conductive stacks that contain titanium nitride and rutile-type titanium oxide, and some embodiments include methods of forming such stacks.

Abstract: An active region structure includes a device region, an active layer and a shallow trench isolation (STI) layer. The device region is defined on a substrate. The active layer is formed by a top portion of the substrate and has a plurality of device cells within the device region and a border structure surrounding the device region. The border structure has at least one branch extending into the device region and is between a portion of the device cells. The STI layer has a first part formed within the border structure to insulate the device cells from one another and a second part surrounding an outer periphery of the border structure. The second part of the STI layer isolates the device cells from a peripheral active region.

Abstract: Some embodiments include methods of forming rutile-type titanium oxide. A monolayer of titanium nitride may be formed. The monolayer of titanium nitride may then be oxidized at a temperature less than or equal to about 550° C. to convert it into a monolayer of rutile-type titanium oxide. Some embodiments include methods of forming capacitors that have rutile-type titanium oxide dielectric, and that have at least one electrode comprising titanium nitride. Some embodiments include thermally conductive stacks that contain titanium nitride and rutile-type titanium oxide, and some embodiments include methods of forming such stacks.

Abstract: Some embodiments include methods of forming rutile-type titanium oxide. A monolayer of titanium nitride may be formed. The monolayer of titanium nitride may then be oxidized at a temperature less than or equal to about 550° C. to convert it into a monolayer of rutile-type titanium oxide. Some embodiments include methods of forming capacitors that have rutile-type titanium oxide dielectric, and that have at least one electrode comprising titanium nitride. Some embodiments include thermally conductive stacks that contain titanium nitride and rutile-type titanium oxide, and some embodiments include methods of forming such stacks.

Abstract: Methods of forming a capacitor including forming a titanium nitride material within at least one aperture defined by a support material, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The titanium nitride material may be oxidized to a titanium dioxide material. A second conductive material may be formed over a surface of the titanium dioxide material. A semiconductor device may include at least one capacitor, wherein a major longitudinal portion of the at least one capacitor is not surrounded by a solid material. The capacitor may include a first electrode; a ruthenium oxide material laterally adjacent the first electrode; a rutile titanium dioxide material laterally adjacent the ruthenium oxide material; and a second electrode laterally adjacent the rutile titanium dioxide material.

Abstract: A 3-D chip stacked structure is disclosed. Each chip layer is provided with plural single-layered conductive members where among the same chip layer the two adjacent conductive members are structurally formed in mirror symmetric way with each other along a chip longitudinal direction and the arrangements of the single-layered conductive members of the two adjacent chip layers are shifted by a test pad distance. The single-layered conductive members of the two adjacent chip layers are communicated through a vertical TSV (through silicon via). Therefore, a selection signal or an enabling signal might be transferred through this specific metal layer and related TSV to reach targeting chip layer and targeting circuit.

Abstract: Methods of forming a capacitor including forming a titanium nitride material within at least one aperture defined by a support material, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The titanium nitride material may be oxidized to a titanium dioxide material. A second conductive material may be formed over a surface of the titanium dioxide material. A semiconductor device may include at least one capacitor, wherein a major longitudinal portion of the at least one capacitor is not surrounded by a solid material. The capacitor may include a first electrode; a ruthenium oxide material laterally adjacent the first electrode; a rutile titanium dioxide material laterally adjacent the ruthenium oxide material; and a second electrode laterally adjacent the rutile titanium dioxide material.

Abstract: Methods of forming a capacitor including forming a titanium nitride material within at least one aperture defined by a support material, forming a ruthenium material within the at least one aperture over the titanium nitride material, and forming a first conductive material over the ruthenium material within the at least one aperture. The titanium nitride material may be oxidized to a titanium dioxide material. A second conductive material may be formed over a surface of the titanium dioxide material. A semiconductor device may include at least one capacitor, wherein a major longitudinal portion of the at least one capacitor is not surrounded by a solid material. The capacitor may include a first electrode; a ruthenium oxide material laterally adjacent the first electrode; a rutile titanium dioxide material laterally adjacent the ruthenium oxide material; and a second electrode laterally adjacent the rutile titanium dioxide material.