A shield trench power device such as a trench MOSFET or IGBT includes a substrate or an epitaxial layer of silicon, silicon carbide, gallium nitride, or gallium arsenide and employs an in-trench structure including a gate structure and an underlying polysilicon or oxide shield region that contacts a shield region in an epitaxial or crystalline layer of the device. The poly silicon region may be laterally confined by spacers in a gate trench and may contact or be isolated from the underlying shield region. Alternatively, the polysilicon region may be replaced with an insulating region.

A vertical field-effect transistor device includes a substrate comprising a semiconductor material, and a set of fins formed from the semiconductor material and extending vertically with respect to the substrate. The vertical field-effect transistor device further includes gate structures disposed on the substrate and on a portion of sidewalls of the set of fins, spacers disposed on the gate structures and on a remaining portion of the sidewalls of the set of fins, source/drain regions disposed over top portions of the set of fins, and a metal liner disposed adjacent and over the source/drain regions such that a wrap-around contact is defined to cover an upper area of the source/drain regions. A portion of the source/drain regions is configured to have a lateral width less than a width between adjacent gate structures on the respective fin.

Semiconductor structure and forming method thereof are provided. The forming method includes: providing a substrate; forming a plurality of initial composite layers on a portion of the substrate; forming a plurality of source and drain layers on surfaces of the plurality of channel layers exposed by a first opening and grooves by using a selective epitaxial growth process, the plurality of source and drain layers being parallel to a first direction and distributed along a second direction, the second direction being parallel to a normal direction of the substrate, and gaps being between adjacent source and drain layers; forming contact layers on surfaces of the plurality of source and drain layers and in the gaps; and forming a conductive structure on a surface of a contact layer on a source and drain layer of the plurality of source and drain layers.

A fin field effect transistor device structure includes a fin structure formed over a substrate. The fin field effect transistor device structure also includes a source/drain epitaxial structure formed over the fin structure. The fin field effect transistor device structure also includes a contact structure with a concave top surface formed over the source/drain epitaxial structure. The fin field effect transistor device structure also includes a barrier layer conformally wrapped around the contact structure. The fin field effect transistor device structure also includes a via structure formed over the contact structure. The concave top surface of the contact structure is below the top surface of the barrier layer.

Methods for reducing interface resistance of semiconductor devices leverage dual work function metal silicide. In some embodiments, a method may comprise selectively depositing a metal silicide layer on an Epi surface and adjusting a metal-to-silicon ratio of the metal silicide layer during deposition to alter a work function of the metal silicide layer based on whether the Epi surface is a P type Epi surface or an N type Epi surface to achieve a Schottky barrier height of less than 0.5 eV. The work function for a P type Epi surface may be adjusted to a value of approximately 5.0 eV and the work function for an N type Epi surface may be adjusted to a value of approximately 3.8 eV. The deposition of the metal silicide layer on the Epi surface may be performed prior to deposition of a contact etch stop layer and an activation anneal.

A semiconductor structure is disclosed. The semiconductor structure includes: a substrate; an active area including a channel region sandwiched between two source/drain regions; an insulation region surrounding the active area from a top view; and a dielectric layer disposed over and in contact with an interface between the insulation region and the source/drain regions. A method of manufacturing the same is also disclosed.

An electrostatic discharge (ESD) protection device, incudes an N-type well and a P-type well formed in a semiconductor substrate; a first N-type diffusion region and a first P-type diffusion region formed in the N-type well, separated by a first separation film, and each connected to an Anode terminal; a second N-type diffusion region and a second P-type diffusion region formed in the P-type well, separated by a second separation film, and each connected to a Cathode terminal; a P-type floating region, formed in the P-type well, spaced apart from the second N-type diffusion region and the second P-type diffusion region; and a non-sal layer covering the P-type floating region.

Improved conductive contacts, methods for forming the same, and semiconductor devices including the same are disclosed. In an embodiment, a semiconductor device includes a first interlayer dielectric (ILD) layer over a transistor structure; a first contact extending through the first ILD layer, the first contact being electrically coupled with a first source/drain region of the transistor structure, a top surface of the first contact being convex, and the top surface of the first contact being disposed below a top surface of the first ILD layer; a second ILD layer over the first ILD layer and the first contact; and a second contact extending through the second ILD layer, the second contact being electrically coupled with the first contact.

The present disclosure relates to semiconductor structures and, more particularly, to bipolar transistors and methods of manufacture. The structure includes: a base region composed of a semiconductor on insulator material; an emitter region above the base region; and a collector region under the base region and within a cavity of a buried insulator layer.

Techniques for reducing the specific contact resistance of metal-semiconductor (group IV) junctions by interposing a monolayer of group V or group III atoms at the interface between the metal and the semiconductor, or interposing a bi-layer made of one monolayer of each, or interposing multiple such bi-layers. The resulting low specific resistance metal-group IV semiconductor junctions find application as a low resistance electrode in semiconductor devices including electronic devices (e.g., transistors, diodes, etc.) and optoelectronic devices (e.g., lasers, solar cells, photodetectors, etc.) and/or as a metal source and/or drain region (or a portion thereof) in a field effect transistor (FET). The monolayers of group III and group V atoms are predominantly ordered layers of atoms formed on the surface of the group IV semiconductor and chemically bonded to the surface atoms of the group IV semiconductor.