A method for manufacturing a semiconductor device having a local interconnect structure includes providing a semiconductor substrate having a gate on an active region, a hardmask layer on the gate, and a first dielectric layer on the gate, etching the first dielectric layer to form a first interconnect trench on the active region, forming a metal silicide layer at a bottom of the first interconnect trench, forming a first metal layer filling the first interconnect trench, forming a second dielectric layer on the gate and the first interconnect trench, etching the second dielectric layer to form a second interconnect trench in a staggered pattern relative to the first interconnect trench, etching the second dielectric layer to form a third interconnect trench, forming a second metal layer in the second interconnect trench and in the third interconnect trench to form the local interconnect structure.

A semiconductor structure is provided that contains silicon fins having different heights, while maintaining a reasonable fin height to width ratio for process feasibility. The semiconductor structure includes a first silicon fin of a first height and located on a pedestal portion of a first oxide structure. The structure further includes a second silicon fin of a second height and located on a pedestal portion of a second oxide structure. The first oxide structure and the second oxide structure are interconnected and the second oxide structure has a bottommost surface that is located beneath a bottommost surface of the first oxide structure. Further, the second height of the second silicon fin is greater than the first height of the first silicon fin, yet a topmost surface of the first silicon fin is coplanar with a topmost surface of the second silicon fin.

A driver IC includes a ring-shaped termination area, and a first area and a second area that are respectively arranged outside and inside the termination area on a layout. A sense MOS that is arranged between a floating terminal and a first sense node and is driven at a power supply voltage is formed in the termination area. A fault detection circuit that detects presence of a fault when a voltage of the first sense node is higher than a decision voltage that has been determined in advance in a period of time that a low side driver is driving a low side transistor into an ON state is formed in the first area.

A semiconductor device includes an active pattern provided on a substrate and a gate electrode crossing over the active pattern. The active pattern includes a first buffer pattern on the substrate, a channel pattern on the first buffer pattern, a doped pattern between the first buffer pattern and the channel pattern, and a second buffer pattern between the doped pattern and the channel pattern. The doped pattern includes graphene injected with an impurity.

A device includes a semiconductor substrate, a doped isolation barrier disposed in the semiconductor substrate to isolate the device, a drain region disposed in the semiconductor substrate and to which a voltage is applied during operation, and a depleted well region disposed in the semiconductor substrate, and having a conductivity type in common with the doped isolation barrier and the drain region. The depleted well region is positioned between the doped isolation barrier and the drain region to electrically couple the doped isolation barrier and the drain region such that the doped isolation barrier is biased at a voltage level lower than the voltage applied to the drain region.

A method for preventing epitaxial growth in a semiconductor device is described. The method includes cutting the fins of FinFET structure to form a set of exposed fin ends. A set of sidewall spacers are formed on the set of exposed fin ends, forming a set of spacer covered fin ends. The set of sidewall spacers prevent epitaxial growth at the set of spacer covered fin ends. A semiconductor device includes a set of fin structures having a set of fin ends. A set of inhibitory layers are disposed at the set of fin ends to inhibit excessive epitaxial growth at the fin ends.

Through-substrate vias (TSVs) include a strain engineering layer configured to minimize or otherwise control local stress fields. The strain engineering layer can be separate from and in addition to a TSV sidewall isolation layer that is deposited along the via sidewall surface for the purpose of electric isolation. For instance, the strain engineering layer can be a partial depth layer that extends over only a portion of the TSV sidewall.

Techniques are disclosed for converting a strain-inducing semiconductor buffer layer into an electrical insulator at one or more locations of the buffer layer, thereby allowing an above device layer to have a number of benefits, which in some embodiments include those that arise from being grown on a strain-inducing buffer and having a buried electrical insulator layer. For instance, having a buried electrical insulator layer (initially used as a strain-inducing buffer during fabrication of the above active device layer) between the Fin and substrate of a non-planar integrated transistor circuit may simultaneously enable a low-doped Fin with high mobility, desirable device electrostatics and elimination or otherwise reduction of substrate junction leakage. Also, the presence of such an electrical insulator under the source and drain regions may further significantly reduce junction leakage. In some embodiments, substantially the entire buffer layer is converted to an electrical insulator.

An integrated circuit on a substrate includes a peripheral portion that surrounds an active area and is positioned close to a scribe line providing separation with other integrated circuits realized on a same wafer. The integrated circuit includes at least one conductive structure that extends in the peripheral portion on different planes of metallizations starting from the substrate and forms an integrated antenna. Another conductive structure extends in the peripheral portion on different planes of metallizations and forms a seal ring.

A two-transistor memory cell based upon a thyristor for an SRAM integrated circuit is described together with a process for fabricating it. The memory cell can be implemented in different combinations of MOS and bipolar select transistors, or without select transistors, with thyristors in a semiconductor substrate with shallow trench isolation. Standard CMOS process technology can be used to manufacture the SRAM.