Techniques for preventing leakage of contact material into air-gap spacers during contact formation. For example, a method comprises forming a contact trench on a semiconductor structure over an air-gap spacer and depositing a liner in the contact trench. The liner deposition material fills a portion of the air-gap spacer pinching off the contact trench to the air-gap spacer.

A production of contact zones for a transistor device including the steps of: a) forming at least one layer made of a compound based on semiconductor and metal on one or more first semiconductor region(s) of a first N-type transistor and on one or more second semiconductor region(s) of a second P-type transistor resting on a same substrate, the first regions being based on a III-V type material whereas the second semiconductor regions are based on another material different from the III-V material, the semiconductor of the compound being an N-type dopant of the III-V material, b) carrying out at least one thermal annealing so as to form on the first semiconductor regions first contact zones and on the second semiconductor regions second contact zones based on a semiconductor and metal compound while increasing the N-doping of the III-V material.

A semiconductor structure is disclosed. The semiconductor structure includes: a substrate; a plurality of gate conductive patterns on the substrate; an interlayer dielectric layer covering the gate conductive patterns on the substrate; an interconnect structure comprising a contact plug and a first contact pad, the contact plug extending through the interlayer dielectric layer to the substrate, the first contact pad fully covering a top of the contact plug and extending laterally over part of a top surface of the interlayer dielectric layer; and a second contact pad formed on the top surface of the interlayer dielectric layer and spaced apart from a side edge of the first contact pad, wherein the second contact pad is formed and fully overlays on the interlayer dielectric layer and an isolation plug is spaced apart from the first contact pad.

A microelectronic unit may include an epitaxial silicon layer having a source and a drain, a buried oxide layer beneath the epitaxial silicon layer, an ohmic contact extending through the buried oxide layer, a dielectric layer beneath the buried oxide layer, and a conductive element extending through the dielectric layer. The source and the drain may be doped portions of the epitaxial silicon layer. The ohmic contact may be coupled to a lower surface of one of the source or the drain. The conductive element may be coupled to a lower surface of the ohmic contact. A portion of the conductive element may be exposed at the second dielectric surface of the dielectric layer. The second dielectric surface may be directly bonded to an external component to form a microelectronic assembly.

A semiconductor structure includes a gate structure on a substrate and a spacer on the substrate and covering sidewalls of the gate structure. The gate structure includes an interfacial layer on the substrate, a high-k dielectric layer on the interfacial layer, and a metal portion on the high-k dielectric layer. The spacer covers sidewalls of the interfacial layer, the high-k dielectric layer, and the metal portion of the gate structure. A bottom width of a portion of the spacer on the sidewall of the interfacial layer is 1.1 times of a middle width of another portion of the spacer on the sidewall of the metal portion.

Methods for forming a semiconductor device structure are provided. The methods may include forming a molybdenum nitride film on a substrate by atomic layer deposition by contacting the substrate with a first vapor phase reactant comprising a molybdenum halide precursor, contacting the substrate with a second vapor phase reactant comprise a nitrogen precursor, and contacting the substrate with a third vapor phase reactant comprising a reducing precursor. The methods provided may also include forming a gate electrode structure comprising the molybdenum nitride film, the gate electrode structure having an effective work function greater than approximately 5.0 eV. Semiconductor device structures including molybdenum nitride films are also provided.

The present invention discloses a semiconductor structure and a method for manufacturing the same, which comprises providing a substrate, and forming a stress layer, a buried oxide layer, and an SOI layer on the substrate; forming a doped region of the stress layer arranged in a specific position in the stress layer; forming an oxide layer and a nitride layer on the SOI layer, and forming a first trench that etches the nitride layer, the oxide layer, the SOI layer, and the buried oxide layer, and stops on the upper surface of the stress layer, and exposes at least part of the doped region of the stress layer; forming a cavity by wet etching through the first trench to remove the doped region of the stress layer; forming a polycrystalline silicon region of the stress layer and a second trench by filling the cavity with polycrystalline silicon and etching back; forming an isolation region by filling the second trench. The semiconductor structure and the method for manufacturing the same disclosed in the present invention provide a favorable stress for the channel of the semiconductor device by introducing a stress layer and a stress induced zone set at specific positions depending on device type to help improving the performance of the semiconductor device.

A method for forming a semiconductor device structure is provided. The semiconductor device structure includes forming a film over a substrate. The semiconductor device structure includes forming a first mask layer over the film. The semiconductor device structure includes forming a second mask layer over the first mask layer. The second mask layer exposes a first portion of the first mask layer. The semiconductor device structure includes performing a plasma etching and deposition process to remove the first portion of the first mask layer and to form a protection layer over a first sidewall of the second mask layer. The first mask layer exposes a second portion of the film after the plasma etching and deposition process. The semiconductor device structure includes removing the second portion using the first mask layer and the second mask layer as an etching mask.

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.

An element isolation portion includes a projection portion that projects from an SOI substrate and comes into contact with a piled-up layer. The height of the upper surface of the projection portion is configured to be lower than or equal to the height of the upper surface of the piled-up layer and higher than or equal to a half of the height of the upper surface of the piled-up layer with reference to a surface of a silicon layer of the SOI substrate.