A semiconductor device includes a substrate, a memory cell region, a peripheral region adjacent to the memory cell region, a plurality of word-lines extending across the memory cell region and the peripheral region, and a plurality of contacts connected to edge portions of even numbered ones of the plurality of word-lines in the peripheral region, respectively.

One feature pertains to an integrated circuit that includes an antifuse having a conductor-insulator-conductor structure. The antifuse includes a first conductor plate, a dielectric layer, and a second conductor plate, where the dielectric layer is interposed between the first and second conductor plates. The antifuse transitions from an open circuit state to a closed circuit state if a programming voltage V.sub.pp greater than or equal to a dielectric breakdown voltage V.sub.BD of the antifuse is applied to the first conductor plate and the second conductor plate. The first conductor plate has a total edge length that is greater than two times the sum of its maximum width and maximum length dimensions. The first conductor plate's top surface area may also be less than the product of its maximum length and maximum width.

A semiconductor device may include a first active region including a first main region and a first protruding part. The semiconductor device may include a second active region including a second main region and a second protruding part. The semiconductor device may include a first transistor formed on the first active region. The semiconductor device may include a second transistor formed on the second active region. The semiconductor device may include a connecting structure connecting the first protruding part and the second protruding part to each other.

A semiconductor memory device includes a first word line formed over a first active region. In some embodiments, a first metal line is disposed over and perpendicular to the first word line, where the first metal line is electrically connected to the first word line using a first conductive via, and where the first conductive via is disposed over the first active region. In some examples, the semiconductor memory device further includes a second metal line and a third metal line both parallel to the first metal line and disposed on opposing sides of the first metal line, where the second metal line is electrically connected to a source/drain region of the first active region using a second conductive via, and where the third metal line is electrically connected to the source/drain region of the first active region using a third conductive via.

A multilayer circuit (400) includes a base layer (205) which has a number of base vias (247, 415), a first overlying layer (215) formed on the base layer (205) and having a first routing section (210) and a second overlying layer (220) formed on the first overlying layer (215). The second overlying layer (220) has a second routing section (210) and is formed using the same set of masks. The first routing section (210) and the second routing section (210) form a unique electrical pathway (248) between a base via (247) and an element in an overlying layer. A method for forming a multilayer circuit is also provided.

Integrated circuits described herein implement an x-input logic gate. The integrated circuit includes a plurality of Schottky diodes that includes x Schottky diodes and a plurality of source-follower transistors that includes x source-follower transistors. Each respective source-follower transistor of the plurality of source-follower transistors includes a respective gate node that is coupled to a respective Schottky diode. A first source-follower transistor of the plurality of source-follower transistors is connected serially to a second source-follower transistor of the plurality of source-follower transistors.

In one embodiment, a semiconductor device includes a substrate, and interconnects provided above the substrate. The device further includes a first insulator that is provided on the interconnects and on air gaps provided between the interconnects, surrounds the interconnects from lateral sides of the interconnects, and is formed of a first insulating material. The device further includes a second insulator that surrounds an interconnect region including the interconnects and the air gaps from the lateral sides of the interconnects through the first insulator, and is formed of a second insulating material different from the first insulating material.

Semiconductor chips are provided. A semiconductor chip includes a peripheral circuit region on a substrate. The semiconductor chip includes a semiconductor layer on the peripheral circuit region. The semiconductor chip includes a cell region on the semiconductor layer. Moreover, the semiconductor chip includes a layer/connector that is adjacent the semiconductor layer. Methods of manufacturing semiconductor chips are also provided.

A semiconductor structure including a semiconductor substrate and at least one patterned dielectric layer is provided. The semiconductor substrate includes a semiconductor portion, at least one first device, at least one second device and at least one first dummy ring. The at least one first device is disposed on a first region surrounded by the semiconductor portion. The at least one second device and the at least one first dummy ring are disposed on a second region, and the second region surrounds the first region. The at least one patterned dielectric layer covers the semiconductor substrate.

A semiconductor device includes a plurality of high-voltage insulated-gate field-effect transistors arranged in a matrix form on the main surface of a semiconductor substrate and each having a gate electrode, a gate electrode contact formed on the gate electrode, and a wiring layer which is formed on the gate electrode contacts adjacent in a gate-width direction to electrically connect the gate electrodes arranged in the gate-width direction. And the device includes shielding gates provided on portions of an element isolation region which lie between the transistors adjacent in the gate-width direction and gate-length direction and used to apply reference potential or potential of a polarity different from that of potential applied to the gate of the transistor to turn on the current path of the transistor to the element isolation region.