A fully depleted field effect transistor (FET) and an anti-fuse structure are provided on a same chip. The fully depleted FET and the anti-fuse structure share a same high dielectric (k) constant dielectric material. The anti-fuse structure contains a faceted epitaxial doped semiconductor material as a bottom electrode, a high k dielectric material portion, and a gate electrode material portion as a top electrode. The sharp corners of the faceted epitaxial doped semiconductor material cause electric field concentration, which aid in the reduction of the breakdown voltage of the anti-fuse structure.

A method for fabricating a semiconductor device includes: implanting a first species into a substrate at a cold temperature to form a first region; and implanting a second species into the substrate at a hot temperature to form a second region that is adjacent to the first region.

A contact structure includes a first contact formed in a first dielectric layer connecting to the source/drain region of a MOS transistor, and a second contact formed in a second dielectric layer connecting to a gate region of a MOS transistor or to a first contact. A butted contact structure abutting a source/drain region and a gate electrode includes a first contact formed in a first dielectric layer connecting to the source/drain region of a MOS transistor, and a second contact formed in a second dielectric layer with one end resting on the gate electrode and the other end in contact with the first contact.

Provided is a semiconductor device with improved performance. The semiconductor device includes a photodiode having a charge storage layer (n-type semiconductor region) and a surface layer (p-type semiconductor region), and a transfer transistor having a gate electrode and a floating diffusion. The surface layer (p-type semiconductor region) of a second conductive type formed over the charge storage layer (n-type semiconductor region) of a first conductive type includes a first sub-region having a low impurity concentration, and a second sub-region having a high impurity concentration. The first sub-region is arranged closer to the floating diffusion than the second sub-region.

Methods are providing for fabricating transistors having at least one source region or drain region with a stressed portion. The methods include: forming, within a cavity of a substrate structure, the at least one source region or drain region with the internal stress; and resurfacing the at least one source region or drain region to reduce surface defects of the at least one source region or drain region without relaxing the stressed portion thereof. For instance, the resurfacing can include melting an upper portion of the at least one source region or drain region. In addition, the resurfacing can include re-crystallizing an upper portion of the at least one source region or drain region, and/or providing the at least one source region or drain region with at least one {111} surface.

The present invention provides a method of forming a passivation layer of a MOS device, and a MOS device. The method of forming a passivation layer of a MOS device includes: forming a substrate; forming a dielectric on the substrate; patterning the dielectric to expose a part of the substrate; forming a metal on the exposed part of the substrate, and the dielectric; forming a TEOS on the metal; forming a PSG on the TEOS; and forming a silicon nitrogen compound on the PSG. Therefore, the cracks problem of the passivation can be alleviated.

A transistor device with a tuned dopant profile is fabricated by implanting one or more dopant migrating mitigating material such as carbon. The process conditions for the carbon implant are selected to achieve a desired peak location and height of the dopant profile for each dopant implant, such as boron. Different transistor devices with similar boron implants may be fabricated with different peak locations and heights for their respective dopant profiles by tailoring the carbon implant energy to effect tuned dopant profiles for the boron.

Embodiments of the present invention provide an improved shallow trench isolation structure and method of fabrication. The shallow trench isolation cavity includes an upper region having a sigma cavity shape, and a lower region having a substantially rectangular cross-section. The lower region is filled with a first material having good gap fill properties. The sigma cavity is filled with a second material having good stress-inducing properties. In some embodiments, source/drain stressor cavities may be eliminated, with the stress provided by the shallow trench isolation structure. In other embodiments, the stress from the shallow trench isolation structure may be used to complement or counteract stress from a source/drain stressor region of an adjacent transistor. This enables precise tuning of channel stress to achieve a desired carrier mobility for a transistor.

A method of treating a semiconductor device is provided including the steps of loading the semiconductor device in a processing chamber, pressurizing the processing chamber by supplying a processing gas from a pressure chamber to the processing chamber, performing a thermal anneal of the semiconductor device in the processing chamber, and depressurizing the processing chamber by supplying the processing gas from the processing chamber to the pressure chamber.

A device including a drain, a channel, and a gate. The channel surrounds the drain and has a channel length to width ratio. The gate is situated over the channel to provide an active channel region that has an active channel region length to width ratio that is greater than the channel length to width ratio.