Abstract: The present disclosure describes a method for forming metal interconnects in an integrated circuit (IC). The method includes placing a metal interconnect in a layout area, determining a location of a redundant portion of the metal interconnect, and reducing, at the location, the length of the metal interconnect by a length of the redundant portion to form one or more active portions of the metal interconnect. The length of the redundant portion is a function of a distance between adjacent gate structures of the IC. The method further includes forming the one or more active portions on an interlayer dielectric (ILD) layer of the IC and forming vias on the one or more active portions, wherein the vias are positioned about 3 nm to about 5 nm away from an end of the one or more active portions.

Abstract: The present disclosure relates to a method includes generating ions with an ion source of an ion implantation apparatus based on an ion implantation recipe. The method includes accelerating the generated ions based on an ion energy setting in the ion implantation recipe and determining an energy spectrum of the accelerated ions. The method also includes analyzing a relationship between the determined energy spectrum and the ion energy setting. The method further includes adjusting at least one parameter of a final energy magnet (FEM) of the ion implantation apparatus based on the analyzed relationship.

Abstract: A method of tuning an ion implantation apparatus is disclosed. The method includes operations of applying any wafer acceptance test (WAT) recipe to a test sample, calculating a recipe for a direct current (DC) final energy magnet (FEM), calculating a real energy of the DC FEM, verifying the tool energy shift, and obtaining a peak spectrum of the DC FEM.

Abstract: The present invention relates to a use of Discoidin Domain Receptor 1 (DDR1) inhibitor in preparing a medicament for preventing or treating a joint disease. The present invention further relates to a use of DDR1 activator in preparing a medicament for preventing or treating abnormalities of endochondral ossification-related conditions.

Abstract: A structure and a formation method of a semiconductor device are provided. The semiconductor device structure includes a first epitaxial structure and a second epitaxial structure over a semiconductor substrate. The semiconductor device structure also includes a first conductive via electrically connected to the first epitaxial structure through a conductive contact. The first conductive via is misaligned with the first epitaxial structure. The semiconductor device structure further includes a second conductive via electrically connected to the second epitaxial structure. The second conductive via is aligned with the second epitaxial structure.

Abstract: A method includes forming an interlayer dielectric (ILD) layer over a first epitaxial source/drain (S/D) feature and a second epitaxial S/D feature, where the first epitaxial S/D feature is disposed adjacent to the second epitaxial S/D feature, forming a dummy contact feature in the ILD layer over the first epitaxial S/D feature, removing a portion of the dummy contact feature and a portion of the ILD layer disposed above the second epitaxial S/D feature to form a first trench, removing a remaining portion of the dummy contact feature to form a second trench, and forming a metal S/D contact in the first and the second trenches.

Abstract: A method of fabricating a semiconductor device is disclosed. The method includes forming a fin structure on a substrate; forming a dummy gate over the fin structure; forming spacers on sides of the dummy gate; forming a doped region within the fin structure; replacing the dummy gate with a metal gate; replacing an upper portion of the metal gate with a first dielectric layer; forming a conductive layer directly on the doped region; replacing an upper portion of the conductive layer with a second dielectric layer; removing the first dielectric layer thereby exposing a sidewall of the spacer; removing an upper portion of the spacer to thereby expose a sidewall of the second dielectric layer; removing at least a portion of the second dielectric layer to form a trench; and forming a conductive plug in the trench.

Abstract: A method includes providing a substrate comprising a material layer and a hard mask layer; patterning the hard mask layer to form hard mask lines; forming a spacer layer over the substrate, including over the hard mask lines, resulting in trenches defined by the spacer layer, wherein the trenches track the hard mask lines; forming a antireflective layer over the spacer layer, including over the trenches; forming an L-shaped opening in the antireflective layer, thereby exposing at least two of the trenches; filling the L-shaped opening with a fill material; etching the spacer layer to expose the hard mask lines; removing the hard mask lines; after removing the hard mask lines, transferring a pattern of the spacer layer and the fill material onto the material layer, resulting in second trenches tracking the pattern; and filling the second trenches with a conductive material.

Abstract: A method includes providing a substrate comprising a material layer and a hard mask layer; patterning the hard mask layer to form hard mask lines; forming a spacer layer over the substrate, including over the hard mask lines, resulting in trenches defined by the spacer layer, wherein the trenches track the hard mask lines; forming a antireflective layer over the spacer layer, including over the trenches; forming an L-shaped opening in the antireflective layer, thereby exposing at least two of the trenches; filling the L-shaped opening with a fill material; etching the spacer layer to expose the hard mask lines; removing the hard mask lines; after removing the hard mask lines, transferring a pattern of the spacer layer and the fill material onto the material layer, resulting in second trenches tracking the pattern; and filling the second trenches with a conductive material.

Abstract: An integrated circuit includes a semiconductor substrate, an isolation region extending into, and overlying a bulk portion of, the semiconductor substrate, a buried conductive track comprising a portion in the isolation region, and a transistor having a source/drain region and a gate electrode. The source/drain region or the gate electrode is connected to the buried conductive track.

Abstract: An integrated circuit includes a semiconductor substrate, an isolation region extending into, and overlying a bulk portion of, the semiconductor substrate, a buried conductive track comprising a portion in the isolation region, and a transistor having a source/drain region and a gate electrode. The source/drain region or the gate electrode is connected to the buried conductive track.

Abstract: The present disclosure describes various non-planar semiconductor devices, such as fin field-effect transistors (finFETs) to provide an example, having one or more metal rail conductors and various methods for fabricating these non-planar semiconductor devices. In some situations, the one or more metal rail conductors can be electrically connected to gate, source, and/or drain regions of these various non-planar semiconductor devices. In these situations, the one or more metal rail conductors can be utilized to electrically connect the gate, the source, and/or the drain regions of various non-planar semiconductor devices to other gate, source, and/or drain regions of various non-planar semiconductor devices and/or other semiconductor devices. However, in other situations, the one or more metal rail conductors can be isolated from the gate, the source, and/or the drain regions these various non-planar semiconductor devices.

Abstract: A 3D-IC includes a first tier device and a second tier device. The first tier device and the second tier device are vertically stacked together. The first tier device includes a first substrate and a first interconnect structure formed over the first substrate. The second tier device includes a second substrate, a doped region formed in the second substrate, a dummy gate formed over the substrate, and a second interconnect structure formed over the second substrate. The 3D-IC also includes an inter-tier via extends vertically through the second substrate. The inter-tier via has a first end and a second end opposite the first end. The first end of the inter-tier via is coupled to the first interconnect structure. The second end of the inter-tier via is coupled to one of: the doped region, the dummy gate, or the second interconnect structure.

Abstract: A method and structure for forming a local interconnect, without routing the local interconnect through an overlying metal layer. In various embodiments, a first dielectric layer is formed over a gate stack of at least one device and a second dielectric layer is formed over a contact metal layer of the at least one device. In various embodiments, a selective etching process is performed to remove the second dielectric layer and expose the contact metal layer, without substantial removal of the first dielectric layer. In some examples, a metal VIA layer is deposited over the at least one device. The metal VIA layer contacts the contact metal layer and provides a local interconnect structure. In some embodiments, a multi-level interconnect network overlying the local interconnect structure is formed.

Abstract: An integrated circuit includes a set of active regions in a substrate, a first set of conductive structures, a shallow trench isolation (STI) region, a set of gates and a first set of vias. The set of active regions extend in a first direction and is located on a first level. The first set of conductive structures and the STI region extend in at least the first direction or a second direction, is located on the first level, and is between the set of active regions. The STI region is between the set of active regions and the first set of conductive structures. The set of gates extend in the second direction and overlap the first set of conductive structures. The first set of vias couple the first set of conductive structures to the set of gates.

Abstract: An integrated circuit includes a semiconductor substrate, an isolation region extending into, and overlying a bulk portion of, the semiconductor substrate, a buried conductive track comprising a portion in the isolation region, and a transistor having a source/drain region and a gate electrode. The source/drain region or the gate electrode is connected to the buried conductive track.

Abstract: A 3D-IC includes a first tier device and a second tier device. The first tier device and the second tier device are vertically stacked together. The first tier device includes a first substrate and a first interconnect structure formed over the first substrate. The second tier device includes a second substrate, a doped region formed in the second substrate, a dummy gate formed over the substrate, and a second interconnect structure formed over the second substrate. The 3D-IC also includes an inter-tier via extends vertically through the second substrate. The inter-tier via has a first end and a second end opposite the first end. The first end of the inter-tier via is coupled to the first interconnect structure. The second end of the inter-tier via is coupled to one of: the doped region, the dummy gate, or the second interconnect structure.

Abstract: A method and structure for forming a local interconnect, without routing the local interconnect through an overlying metal layer. In various embodiments, a first dielectric layer is formed over a gate stack of at least one device and a second dielectric layer is formed over a contact metal layer of the at least one device. In various embodiments, a selective etching process is performed to remove the second dielectric layer and expose the contact metal layer, without substantial removal of the first dielectric layer. In some examples, a metal VIA layer is deposited over the at least one device. The metal VIA layer contacts the contact metal layer and provides a local interconnect structure. In some embodiments, a multi-level interconnect network overlying the local interconnect structure is formed.

Abstract: Vertical gate all-around (VGAA) structures are described. In an embodiment, a structure including a first doped region in a substrate, a first vertical channel extending from the first doped region, a first metal-semiconductor compound region in a top surface of the first doped region, the first metal-semiconductor compound region extending along at least two sides of the first vertical channel, and a first gate electrode around the first vertical channel.

Abstract: A semiconductor device and a method for fabricating the semiconductor device are provided. The semiconductor device includes a semiconductor substrate, a gate structure including a gate dielectric layer and a first gate electrode layer, and a second gate electrode layer. In the method for fabricating the semiconductor device, at first, the semiconductor substrate is provided. The semiconductor substrate includes fin portions. Then, a gate dielectric layer is formed on the fin portions. Thereafter, a first gate electrode layer is formed on the gate dielectric layer. Then, the first gate electrode layer is etched. Thereafter, a second electrode layer is formed on the first gate electrode layer. Therefore, the gate electrode layer formed on the gate dielectric layer is regrown with easy control.