A semiconductor structure includes a substrate, a first transistor and a second transistor. The substrate includes a semiconductor-on-insulator region and a bulk region. The first transistor is provided at the semiconductor-on-insulator region and includes a first gate structure and a first channel region provided in a layer of semiconductor material over a layer of electrically insulating material. The second transistor is provided at the bulk region and includes a second gate structure and a second channel region provided in a bulk semiconductor material. A plane of an interface between the second channel region and the second gate structure is not above a plane of an interface between the bulk semiconductor material and the layer of electrically insulating material in the semiconductor-on-insulator region. A height of the second gate structure is greater than a height of the first gate structure.

A method for making a semiconductor device may include forming a semiconductor layer, and forming a superlattice adjacent the semiconductor layer and including stacked groups of layers. Each group of layers may include stacked base semiconductor monolayers defining a base semiconductor portion, and at least one oxygen monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The at least one oxygen monolayer of a given group of layers may comprise an atomic percentage of .sup.18O greater than 10 percent.

A method and structure is provided in which germanium or a germanium tin alloy can be used as a channel material in either planar or non-planar architectures, with a functional gate structure formed utilizing either a gate first or gate last process. After formation of the functional gate structure, and contact openings within a middle-of-the-line (MOL) dielectric material, a hydrogenated silicon layer is formed that includes hydrogenated crystalline silicon regions disposed over the germanium or a germanium tin alloy, and hydrogenated amorphous silicon regions disposed over dielectric material. The hydrogenated amorphous silicon regions can be removed selective to the hydrogenated crystalline silicon regions, and thereafter a contact structure is formed on the hydrogenated crystalline silicon regions.

A semiconductor device and method of formation are provided herein. A semiconductor device includes a barrier including carbon over a fin, the fin including a doped region. The semiconductor device includes an epitaxial (Epi) cap over the barrier, the Epi cap including phosphorus. The barrier inhibits phosphorus diffusion from the Epi cap into the fin as compared to a device that lacks such a barrier. The inhibition of the phosphorus diffusion reduces a short channel effect, thus improving the semiconductor device function.

Method of making a transistor, comprising the following steps: make a gate and a first spacer on a first channel region of a first crystalline semiconducting layer; make first crystalline semiconductor portions on the second source and drain regions; make the second regions amorphous and dope them; recrystallise the second regions and activate the dopants present in the second regions; remove the first portions; make a second spacer thicker than the first spacer; make second doped crystalline semiconductor portions on the second regions, said second portions and the second regions of the first layer together form the source and drain of the transistor.

Embodiments of the invention provide a wrap-around contact integration scheme that includes sidewall protection during contact formation. A substrate processing method includes providing a substrate containing a raised contact in a first dielectric film, and a second dielectric film on the first dielectric film, where the second dielectric film has a recessed feature with a sidewall and a bottom portion above the raised contact. The method further includes depositing a conformal film on the sidewall and on the bottom portion of the recessed feature, removing the conformal film from the bottom portion in a first anisotropic etching process, where the remaining conformal film forms a protection film on the sidewall and defines a width of the recessed feature, and forming a cavity containing the raised contact in an isotropic etching process, where a width of the cavity is greater than the width of the recessed feature.

A field-effect transistor, including a source, drain and channel formed in a semiconductor layer a gate stack placed above the channel, including a metal electrode, a first layer of electrical insulator placed between the metal electrode and the channel, and a second layer of electrical insulator covering the metal electrode; a metal contact placed plumb with the source or drain and at least partially plumb with said gate stack; and a third layer of electrical insulator placed between said metal contact and said source or said drain.

A semiconductor device structure is provided. The semiconductor device structure includes a substrate having a fin structure that includes a first negative capacitance material, and an isolation structure formed over the substrate. The semiconductor device structure includes a gate structure formed over the fin structure, and a source feature and a drain feature formed over the fin structure. An interface between the fin structure and the source feature is lower than a top surface of the isolation structure.

Discussed herein is device contact sizing in integrated circuit (IC) structures. In some embodiments, an IC structure may include: a first source/drain (S/D) contact in contact with a first S/D region, and a second S/D contact in contact with a second S/D region, wherein the first S/D region and the second S/D region have a same length, and the first S/D contact and the second S/D contact have different lengths.

A method includes: forming a dielectric fin protruding above a substrate; forming a channel layer over an upper surface of the dielectric fin and along first sidewalls of the dielectric fin, the channel layer including a low dimensional material; forming a gate structure over the channel layer; forming metal source/drain regions on opposing sides of the gate structure; forming a channel enhancement layer over the channel layer; and forming a passivation layer over the gate structure, the metal source/drain regions, and the channel enhancement layer.