In some embodiments, the present disclosure relates to method of forming an integrated chip. The method includes forming a bottom electrode structure over one or more interconnect layers disposed within one or more stacked inter-level dielectric (ILD) layers over a substrate. The bottom electrode structure has an upper surface having a noble metal. A diffusion barrier film is formed over the bottom electrode structure. A data storage film is formed onto the diffusion barrier film, and a top electrode structure is over the data storage film. The top electrode structure, the data storage film, the diffusion barrier film, and the bottom electrode structure are patterned to define a memory device.

A semiconductor device includes a substrate including cell and peripheral regions. Landing pads and contact plugs are on the cell and peripheral regions, respectively. A first filler pattern fills regions between the landing pads and between the contact plugs. Outer voids are in the first filler pattern and include first and second outer voids on the cell and peripheral regions, respectively. A second filler pattern covers the first filler pattern and the contact plugs and fills at least a portion of the second outer void. An inner void is in the second outer void and enclosed by the second filler pattern. The first and second filler patterns include the same material. On the cell region, at least a portion of the second filler pattern is located below top surfaces of the landing pads, and a bottom surface of the second filler pattern is partially exposed by the first outer void.

A tunneling field-effect transistor (TFET) device is disclosed. A frustoconical protrusion structure is disposed over the substrate and protrudes out of the plane of substrate. A drain region is disposed over the substrate adjacent to the frustoconical protrusion structure and extends to a bottom portion of the frustoconical protrusion structure as a raised drain region. A gate stack is disposed over the substrate. The gate stack has a planar portion, which is parallel to the surface of substrate and a gating surface, which wraps around a middle portion of the frustoconical protrusion structure, including overlapping with the raised drain region. An isolation dielectric layer is disposed between the planar portion of the gate stack and the drain region. A source region is disposed as a top portion of the frustoconical protrusion structure, including overlapping with a top portion of the gating surface of the gate stack.

Various embodiments provide semiconductor devices and methods for forming the same. A first fin and a second fin are formed on a semiconductor substrate. A first dielectric layer is formed on the semiconductor substrate and has a top surface lower than a top surface of both of the first fin and the second fin. A gate structure is formed on the first dielectric layer and covering across a first portion of each of the first fin and the second fin. A second portion of the first fin on both sides of the gate structure is removed, forming a first recess. A first semiconductor layer is formed in the first recess. A second dielectric layer is formed on the first dielectric layer and the first semiconductor layer, and exposes a top surface of the second fin. A second semiconductor layer is formed on the exposed top surface of the second fin.

A semiconductor device structure is provided. The semiconductor device structure includes a gate stack over a semiconductor substrate and a source/drain structure adjacent to the gate stack. The semiconductor device structure also includes a cap element over the source/drain structure. The cap element has a first top plane, and the source/drain structure has a second top plane. The first top plane of the cap element is wider than the second top plane of the source/drain structure. A surface orientation of the first top plane of the cap element and a surface orientation of a side surface of the cap element are different from each other. The surface orientation of the first top plane of the cap element is {311}.

An integrated circuit device and method for manufacturing the integrated circuit device are disclosed. The disclosed method comprises forming a wedge-shaped recess with an initial bottom surface in the substrate; transforming the wedge-shaped recess into an enlarged recess with a height greater than the height of the wedge-shaped recess; and epitaxially growing a strained material in the enlarged recess.

The present disclosure provides a method for fabricating an integrated circuit device. The method includes providing a precursor including a substrate having first and second metal-oxide-semiconductor (MOS) regions. The first and second MOS regions include first and second gate regions, semiconductor layer stacks, and source/drain regions respectively. The method further includes laterally exposing and oxidizing the semiconductor layer stack in the first gate region to form first outer oxide layer and inner nanowire set, and exposing the first inner nanowire set. A first high-k/metal gate (HK/MG) stack wraps around the first inner nanowire set. The method further includes laterally exposing and oxidizing the semiconductor layer stack in the second gate region to form second outer oxide layer and inner nanowire set, and exposing the second inner nanowire set. A second HK/MG stack wraps around the second inner nanowire set.

A semiconductor device and method of formation are provided. The semiconductor device includes a first active region adjacent a channel, the channel, and a second active region adjacent the channel. The channel has a channel doping profile. The channel includes a central channel portion having a first dopant concentration of a first dopant and a radial channel portion surrounding the central channel portion. The radial channel portion has a second dopant concentration of a second dopant greater than the first dopant concentration. The channel comprising the central channel portion and the radial channel portion has increased voltage threshold tuning as compared to a channel that lacks a central channel portion and a radial channel portion.

A method for fabricating semiconductor device is disclosed. The method includes the steps of: providing a substrate; forming a fin-shaped structure on the substrate; forming a shallow trench isolation (STI) around the fin-shaped structure; forming a gate structure on the fin-shaped structure and the STI and the fin-shaped structure directly under the gate structure includes a first epitaxial layer; forming a source region having first conductive type adjacent to one side of the gate structure; and forming a first drain region having a second conductive type adjacent to another side of the gate structure.

The present disclosure provides a semiconductor device structure including a non-volatile memory (NVM) device structure in and above a first region of a semiconductor substrate and a logic device formed in and above a second region of the semiconductor substrate different from the first region. The NVM device structure includes a floating-gate, a first select gate and at least one control gate. The logic device includes a logic gate disposed on the second region and source/drain regions provided in the second region adjacent to the logic gate. The control gate extends over the floating-gate and the first select gate is laterally separated from the floating-gate by an insulating material layer portion. Upon forming the semiconductor device structure, the floating gate is formed before forming the control gate and the logic device.