Provided is a semiconductor structure, configured to form a pad, including a substrate, a top-layer conductive line, N layers of secondary-top-layer conductive lines and a plurality of dielectric layers, N being an integer greater than or equal to 2. The top-layer conductive line and the N layers of the secondary-top-layer conductive lines are arranged above the substrate. The N layers of the secondary-top-layer conductive lines are arranged on a side of the top-layer conductive line close to the substrate. Each of the plurality of dielectric layers is located between two respective adjacent layers of the secondary-top-layer conductive lines in a vertical direction. For the N layers of the secondary-top-layer conductive lines, an area in which projections of any two layers of the secondary-top-layer conductive lines on a top surface of the substrate overlap with each other is less than a first threshold.

A semiconductor device according to an embodiment includes: a first trench and a second trench extending in a first direction; a first gate electrode in the first trench; a second gate electrode in the second trench; a first gate wire including a first portion extending in a second direction perpendicular to the first direction and a third portion extending in the second direction; a second gate wire including a first portion extending in the second direction and a third portion extending in the second direction; a first gate electrode pad; and a second gate electrode pad. The first portion of the second gate wire is between the first portion and the third portion of the first gate wire, and the third portion of the first gate wire is between the first portion and the third portion of the second gate wire.

A semiconductor device includes a substrate and a metallization layer. The substrate has an active region that includes opposite first and second edges. The metallization layer is disposed above the substrate, and includes a pair of metal lines and a metal plate. The metal lines extend from an outer periphery of the active region into the active region and toward the second edge of the active region. The metal plate interconnects the metal lines and at least a portion of which is disposed at the outer periphery of the active region.

A semiconductor device includes: a substrate; a first nitride semiconductor layer on the substrate; a second nitride semiconductor layer on the first nitride semiconductor layer; finger-shaped source electrodes on the second nitride semiconductor layer; finger-shaped drain electrodes disposed so as to be spaced apart from the source electrodes; and finger-shaped gate electrodes respectively disposed between the source electrodes and the drain electrodes. The gate electrodes are electrically connected, via a first gate integrated wiring, a plurality of second gate integrated wirings and a third gate integrated wiring, to gate pads located on one or both ends of the third gate integrated wiring. A plurality of source pads and the plurality of second gate integrated wirings are formed alternately in a first direction perpendicular to the longitudinal direction of the gate electrodes.

A lateral power semiconductor device structure comprises a pad-over-active topology wherein on-chip interconnect metallization and contact pad placement is optimized to reduce interconnect resistance. For a lateral GaN HEMT, wherein drain, source and gate finger electrodes extend between first and second edges of an active region, the source and drain buses run across the active region at positions intermediate the first and second edges of the active region, interconnecting first and second portions of the source fingers and drain fingers which extend laterally towards the first and second edges of the active region. External contact pads are placed on the source and drain buses. For a given die size, this interconnect structure reduces lengths of current paths in the source and drain metal interconnect, and provides, for example, at least one of lower interconnect resistance, increased current capability per unit active area, and increased active area usage per die.

Provided is a semiconductor device in which the reliability of the gate insulating film in a trench gate is improved. The semiconductor device includes a semiconductor substrate, a plurality of trench gates, and a gate electrode. The semiconductor substrate includes an active region and a wiring region. The trench gates extend from the first active region to the wiring region. The trench gates form parts of transistors in the active region. The gate electrode is provided in the wiring region and is electrically connected to the trench gates. The end portions of the trench gates are located in the wiring region. The gate electrode is provided so as to cover gate contact portions formed at the end portions of the trench gates. The gate electrode is electrically connected to trench gates via the gate contact portions. The plurality of trench gates extend only in one direction.

An SRAM array circuit in which a horizontal N-well of a well tap cell in a first row separated from a horizontal N-well of a well tap cell in a second row by a P-type substrate region is disclosed. The well tap cells include a bilateral P-type well tap disposed in the P-type substrate region between the horizontal N-wells in the first and second rows providing ground voltage to the P-type substrate on both sides of a column of well tap cells in the SRAM array circuit, rather than one P-type well tap for each side. Well tap cells without a vertical N-well reduces width, which corresponds to a reduction in width of the SRAM array circuit. The bilateral P-type well tap in a P-type implant region may include a plurality of folded fingers providing the ground voltage to the P-type substrate.

A first interconnect on an interconnect level connects a first subset of PMOS drains together of a CMOS device. A second interconnect on the interconnect level connects a second subset of the PMOS drains together. The second subset of the PMOS drains is different than the first subset of the PMOS drains. The first interconnect and the second interconnect are disconnected on the interconnect level. A third interconnect on the interconnect level connects a first subset of NMOS drains together of the CMOS device. A fourth interconnect on the interconnect level connects a second subset of the NMOS drains together. The second subset of the NMOS drains is different than the first subset of the NMOS drains. The third interconnect and the fourth interconnect are disconnected on the interconnect level. The first, second, third, and fourth interconnects are coupled together through at least one other interconnect level.

High power transistors, such as high power gallium nitride (GaN) transistors, are described. These high power transistors have larger total gate widths than conventional high power transistors by arranging multiple linear arrays of contacts in parallel. Thereby, the total gate width and the power rating of a high power transistor may be increased without elongating the die of the high power transistor. Accordingly, the die of the high power transistor may be mounted in a smaller circuit package relative to conventional dies with the same power rating.

Pursuant to some embodiments of the present invention, transistor devices are provided that include a semiconductor structure, a drain finger extending on the semiconductor structure in a first direction, and a drain interconnect extending in the first direction and configured to be coupled to a drain signal at an interior position of the drain interconnect, where the drain interconnect is connected to the drain finger at a position offset from the interior position of the drain interconnect.