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.

A semiconductor device includes a silicon substrate; a semiconductor fin over the silicon substrate; and an isolation structure over the silicon substrate. The semiconductor fin includes a first portion and a second portion over the first portion. The first portion is surrounded by the isolation structure, and the second portion protrudes above the isolation structure. The second portion has a different crystalline lattice constant than the first portion. The first portion includes a first dopant, and the second portion is substantially free of the first dopant. The semiconductor device further includes a gate structure above the isolation structure and engaging multiple surfaces of the second portion.

A method of forming a semiconductor device includes performing a first implantation process on a semiconductor substrate to form a deep p-well region, performing a second implantation process on the semiconductor substrate with a diffusion-retarding element to form a co-implantation region, and performing a third implantation process on the semiconductor substrate to form a shallow p-well region over the deep p-well region. The co-implantation region is spaced apart from a top surface of the semiconductor substrate by a portion of the shallow p-well region, and the dee p-well region and the shallow p-well region are joined with each other. An n-type Fin Field-Effect Transistor (FinFET) is formed, with the deep p-well region and the shallow p-well region acting as a well region of the n-type FinFET.

Electrical overstress protection for high speed applications is provided. In certain embodiments, a method of distributed and customizable electrical overstress protection for a semiconductor die is provided. The method includes configuring a heterogeneous overstress protection array that includes a customizable forward protection circuit electrically connected between a power high pad, a power low pad, and a signal pad and distributed across the semiconductor die, including selecting a number of segmented overstress protection devices from a plurality of available overstress protection devices of the customizable protection circuit. The method also includes choosing a device type of the selected segmented overstress protection devices from amongst two or more different device types providing complementary protection characteristics and protecting a core circuit from electrical overstress using the selected segmented overstress protection devices, the core circuit electrically connected to at least the signal pad, the power high pad, and the power low pad.

The present invention provides a new complementary MOSFET structure with localized isolations in silicon substrate to reduce leakages and prevent latch-up. The complementary MOSFET structure comprises a semiconductor wafer substrate with a semiconductor surface, a P type MOSFET comprising a first conductive region, a N type MOSFET comprising a second conductive region, and a cross-shape localized isolation region between the P type MOSFET and the N type MOSFET. Wherein, the cross-shape localized isolation region includes a horizontally extended isolation region below the semiconductor surface, and the horizontally extended isolation region contacts to a bottom side of the first conductive region and a bottom side of the second conductive region.

A semiconductor device includes a first well, a first region and fourth regions of a first conductivity type as well as second regions, a third region, a second well of the second conductivity type. A first region is disposed in the first well and coupled to a first reference voltage terminal. Second regions are disposed in the first well, wherein one of the second regions is coupled to the first reference voltage terminal, and the second regions and the first well are included in a first transistor. A third region is disposed in the first well. A first resistive load is coupled between the third region and a second reference voltage terminal. A second well is coupled to the first well. Fourth regions are disposed in the second well, wherein the second well and at least one of the fourth regions are included in a second transistor.

The present disclosure describes a metal-oxide-semiconductor field-effect transistor (MOSFET) device. The MOSFET device includes a first-type substrate, a deep-second-type well in the first-type substrate, a first-type well over the deep-second-type well, and a second-type well over the deep-second-type well. The second-type well and the deep-second-type well form an enclosed space that includes the first-type well. The MOSFET also includes an embedded semiconductor region (ESR) in a vicinity of the enclosed space. The ESR includes a dopant concentration lower than at least one of a dopant concentration of the first-type well, a dopant concentration of the second-type well, and a dopant concentration of the deep-second-type well.

Embodiment provides an integrated circuit latch-up test structure. The circuit includes: a first P-type heavily doped region, a first N-type heavily doped region, a second P-type heavily doped region, and a second N-type heavily doped region. A first distance is provided between the first P-type heavily doped region and the first N-type heavily doped region, a second distance is provided between the first N-type heavily doped region and the second P-type heavily doped region, and a third distance is provided between the second P-type heavily doped region and the second N-type heavily doped region. The test structure is configured to test electrical parameters of a latch-up effect of an integrated circuit corresponding to the test structure by adjusting at least one of the first distance, the second distance, and the third distance.

There is provided a logic circuit capable of preventing latch-up. The conducting of a parasitic SCR is prevented by doping an additional N+ active region in the N well region of a PMOS transistor and doping an additional P+ active region in the P well region of an NMOS transistor so as to prevent the occurrence of latch-up.

A semiconductor device includes a first to sixth regions, a first gate, a first metal contact and a second metal contact. The second region is disposed opposite to the first region with respect to the first gate. The first metal contact couples the first region to the second region. The fourth region is disposed opposite to the third region with respect to the first gate. The second metal contact is coupling the third region to the fourth region. The fifth region is disposed between the first gate and the second region, and is disconnected from the first metal contact and the second metal contact. The sixth region is disposed between the first gate and the first region, and is disconnected from the first metal contact and the second metal contact.