In an embodiment, an integrated circuit (IC) device comprises a semiconductor substrate, an isolation region and an active region disposed on the semiconductor substrate, a gate stack disposed over the active region, and a source and a drain disposed in the active region and interposed by the gate stack in a first direction. The active region is at least partially surrounded by the isolation region. A middle portion of the active region laterally extends beyond the gate stack in a second direction that is perpendicular to the first direction.

A semiconductor structure includes a semiconductor substrate, a trench being provided in the semiconductor substrate, and a gate being formed in the trench; an ion implantation layer located in the semiconductor substrate outside the trench, a top surface of the ion implantation layer being higher than that of the gate, and a bottom surface of the ion implantation layer being lower than the top surface of the gate and higher than a bottom surface of the gate; a transition layer located between the gate and the ion implantation layer, a bottom surface of the transition layer being lower than the top surface of the gate and higher than the bottom surface of the gate, and a doping concentration of the transition layer being lower than that of the ion implantation layer.

The invention provides a method for forming a semiconductor structure. The method includes providing a substrate, forming a gate structure on the substrate, respectively forming an epitaxial layer on both sides of the gate structure, and performing a pre-amorphization doping step on the substrate. After the pre-amorphization doping step, a defect is generated in the epitaxial layer, an outer spacer is formed beside the gate structure, and a chemical cleaning step is performed to remove a part of the epitaxial layer, and the defect in the epitaxial layer is removed.

An NVM device includes a semiconductor substrate, a first floating gate, a first control gate, a first drain region, and a common source region. The semiconductor substrate has a recess extending downward from the substrate surface. The first floating gate is disposed in the recess, has a base and a side wall connecting to the base. The first control gate is disposed on and adjacent to the first floating gate. The first drain region is disposed in the semiconductor substrate in the recess. The common source region is formed in the semiconductor substrate in the recess, is adjacent to the first floating gate, and includes a main body and an extension part. The main body is disposed below a bottom surface of the recess and adjacent to the base. The extension part extends upward from the bottom surface beyond the base to be adjacent to the side wall.

A includes depositing a gate electrode layer over a semiconductor substrate; patterning the gate electrode layer into a first gate electrode and a gate electrode extending portion; forming a first gate spacer alongside the first gate electrode; patterning the gate electrode extending portion into a second gate electrode after forming the first gate spacer; and forming a second gate spacer alongside the second gate electrode and a third gate spacer around the first spacer.

A method for forming a semiconductor structure includes: providing a substrate, in which a gate structure is formed on the substrate; forming first side walls covering side surfaces of the gate structure, in which the first side walls have a first preset thickness in a direction parallel to a plane of the substrate; performing first ion implantation on the substrate on both sides of the gate structure exposed to the first side walls; removing a part of the first side walls to form second side walls, in which the second side walls have a second preset thickness in the direction parallel to the plane of the substrate; and performing second ion implantation on the substrate on both sides of the gate structure, in which doping types of the first ion implantation and the second ion implantation are different.

This application discloses an NMOS device and an integrated circuit. The NMOS device includes a semiconductor substrate, a gate oxide layer, and a gate. The semiconductor substrate includes a P well, a source region, a drain region, a first LDD region, and a second LDD region. The first LDD region and the second LDD region each include a first ion injection region and a second ion injection region. The first ion injection region is formed by injecting a first ion, and the first ion includes a P ion. The second ion injection region is formed by injecting a second ion into the first ion injection region, and the second ion includes a Ge ion.

A method including forming an opening in a junction region of a fin on and extending from a substrate; introducing a doped semiconductor material in the opening; and thermal processing the doped semiconductor material. A method including forming a gate electrode on a fin extending from a substrate; forming openings in the fin adjacent opposite sides of the gate electrode; introducing a doped semiconductor material in the openings; and thermally processing the doped semiconductor material sufficient to induce the diffusion of a dopant in the doped semiconductor material. An apparatus including a gate electrode transversing a fin extending from a substrate; and semiconductor material filled openings in junction regions of the fin adjacent opposite sides of the gate electrode, wherein the semiconductor material comprises a dopant.

A method for fabricating p-type field effect transistor (FET) includes the steps of first providing a substrate, forming a pad layer on the substrate, forming a well in the substrate, performing an ion implantation process to implant germanium ions into the substrate to form a channel region, and then conducting an anneal process to divide the channel region into a top portion and a bottom portion. After removing the pad layer, a gate structure is formed on the substrate and a lightly doped drain (LDD) is formed adjacent to two sides of the gate structure.

A non-volatile memory device is provided. The non-volatile memory device includes a substrate having an active region, a source region, a drain region, and a floating gate. The source region and the drain region may be arranged in the active region, the drain region may be arranged adjacent to the source region. The source region and the drain region may define a channel region therebetween. The floating gate may be arranged over the active region, and may include a first section over the channel region, a plurality of second sections over the drain region, and a connecting section arranged between the first section and the plurality of second sections