An integrated circuit includes a compressive stressor and a tensile stressor, each located directly over an active region of a transistor, where a portion of the compressive stressor and a portion of the tensile stressor directly overlap with each other. In some embodiments, utilizing a compressive stressor and tensile stressor located directly over an active region with overlapping portions may allow for an adjustment of the stress applied to a channel region of a transistor to compensate for stress imparted by package structures.

A semiconductor structure includes an isolation structure, a source/drain region over the isolation structure, a gate structure over the isolation structure and adjacent to the source/drain region, an interconnect layer over the source/drain region and the gate structure, an isolating layer below the gate structure, and a contact structure under the source/drain region. The contact structure has a first portion and a second portion. The first portion is below the second portion. The second portion extends through the isolating layer and protrudes above the isolating layer. A portion of the isolating layer is vertically between the gate structure and the first portion of the contact structure.

Gate-all-around integrated circuit structures having differential nanowire thickness and gate oxide thickness, and methods of fabricating gate-all-around integrated circuit structures having differential nanowire thickness and gate oxide thickness, are described. For example, an integrated circuit structure includes a nanowire with an outer thickness and an inner thickness, the inner thickness less than the outer thickness. The nanowire tapers from outer regions having the outer thickness to an inner region having the inner thickness. A dielectric material is on and surrounding the nanowire such that a combined thickness of the nanowire and the dielectric material in the inner region is approximately the same as the outer thickness of the nanowire.

A semiconductor device and fabrication method are described for integrating a nanosheet transistor with a multimodal transistor (MMT) in a single nanosheet process flow by processing a wafer substrate to form buried metal source/drain structures in an MMT region that are laterally spaced apart from one another and positioned below an MMT semiconductor channel layer before forming a transistor stack of alternating Si and SiGe layers in an FET region which are selectively processed to form gate electrode openings so that a first ALD oxide and metal layer are patterned and etched to form gate electrodes in the transistor stack and to form a channel control gate electrode over the MMT semiconductor channel layer, and so that a second oxide and conductive layer are patterned and etched to form a current control gate electrode over the MMT semiconductor channel layer and adjacent to the channel control gate electrode.

A semiconductor device is provided. The semiconductor device includes a substrate and channel structures stacked over each other along a first direction substantially perpendicular to a working surface of the substrate and each configured to have a current direction along a second direction substantially parallel to the working surface of the substrate. Source/drain (S/D) structures are positioned on opposing sides of the channel structure along the second direction. Gate structures are positioned on opposite sides of the channel structures along a third direction substantially parallel to the working surface of the substrate. The channel structures each have a shape of a nanosheet extending substantially perpendicular to the working surface of the substrate.

A method includes following steps. A first transistor is formed on a substrate. A first dielectric layer is formed over the first transistor. A first trench is formed in the first dielectric layer. An amorphous semiconductor layer is deposited in the first trench and over the first dielectric layer. The amorphous semiconductor layer is crystallized into a crystalline semiconductor layer. A second transistor is formed over the crystalline semiconductor layer.

Embodiments of the invention include forming a first transistor having first nanosheets, first dipole gate dielectric material being formed around the first nanosheets. An aspect includes forming a second transistor comprising second nanosheets, second dipole gate dielectric material being formed around the second nanosheets, the first and second transistors being in a vertical stack, a first spacing between the first nanosheets being different from a second spacing between the second nanosheets. An aspect includes forming a workfunction metal stack having a first workfunction metal and a second workfunction metal, the first and second workfunction metals being formed between the first nanosheets, the first workfunction metal being formed to pinch off in the second spacing between the second nanosheets such that the second workfunction metal is absent in the second spacing between the second nanosheets.

A semiconductor device is provided. A substrate includes a first region and a second region. A first wire pattern, extending in a first direction, is formed at a first height from the substrate of the first region. A second wire pattern, extending in a second direction, is formed at a second height from the substrate of the second region. The first height is different from the second height. A first gate electrode, surrounding the first wire pattern, extends in a third direction crossing the first direction. A second gate electrode, surrounding the second wire pattern, extends in a fourth direction crossing the second direction. A first gate insulation layer is formed along a circumference of the first wire pattern and a sidewall of the first gate electrode. A second gate insulation layer is formed along a circumference of the second wire pattern and a sidewall of the second gate electrode.

An n-type field effect transistor includes semiconductor channel members vertically stacked over a substrate, a gate dielectric layer wrapping around each of the semiconductor channel members, and a work function layer disposed over the gate dielectric layer. The work function layer wraps around each of the semiconductor channel members. The n-type field effect transistor also includes a WF isolation layer disposed over the WF layer and a gate metal fill layer disposed over the WF isolation layer. The WF isolation layer fills gaps between adjacent semiconductor channel members.

A semiconductor device includes a substrate having an I/O region and a core region; a first transistor in the I/O region; and a second transistor in the core region, wherein the first transistor includes a first gate structure having: an interfacial layer; a first high-k region over the interfacial layer; and a conductive layer over the first high-k region, wherein the second transistor includes a second gate structure having: the interfacial layer; a second high-k region over the interfacial layer; and the conductive layer over the second high-k region, and where in the first high-k region is thicker than the second high-k region.