An integrated device comprising a buried oxide layer within a trench within a top surface of a substrate. A silicon layer formed over the buried oxide layer and the top surface of the substrate.

A semiconductor device includes a semiconductor layer with an inner portion, an outer portion laterally surrounding the inner portion, and a transition portion laterally surrounding the inner portion and separating the inner portion and the outer portion. A first electric element includes a first doped region formed in the inner portion and a second doped region formed in the outer portion. The first electric element is configured to at least temporarily block a voltage applied between the first doped region and the second doped region. A trench isolation structure extends from a first surface into the semiconductor layer and segments at least one of the inner portion, the transition portion, and the outer portion.

Integrated circuit structures having conductive structures in fin isolation regions are described. In an example, an integrated circuit structure includes a vertical stack of horizontal nanowires over a sub-fin. The integrated circuit structure also includes a gate structure. The gate structure includes a first gate structure portion over the vertical stack of horizontal nanowires, a second gate structure portion laterally adjacent to the first gate structure portion, wherein the second gate structure portion is not over a channel structure, and a gate cut between the first gate structure portion and the second gate structure portion.

A method for manufacturing a semiconductor-on-insulator (SeOI) chip comprises: a) providing a SeOI structure, b) building a plurality of isolated field effect transistors (FET) each comprising: a preliminary gate above a channel region, the FETs from a first group having a first preliminary gate length and the FETs from a second group having a smaller second preliminary gate length, a source region and a drain region, and a source electrode and a drain electrode, c) removing at least the preliminary gates of the FETs from the second group, leaving access to channel regions of the FETs, d) thinning a top layer in channel regions of the FETs from the second group, the top layer in channel regions of the first group of FETs having a different thickness, and e) forming functional gates simultaneously on channel regions of the FETs whose preliminary gates were removed.

A semiconductor device includes a first buried layer and a second buried layer both have a first conductivity type and are disposed in a substrate, where the second buried layer is disposed on the first buried layer. A first well region has the first conductivity type and is disposed above the second buried layer. A second well region has a second conductivity type and is adjacent to the first well region. A deep trench isolation structure is disposed in the substrate and surrounds the first and second well regions, where the bottom surface of the deep trench isolation structure is lower than the bottom surface of the first buried layer. A source region is disposed in the second well region. A drain region is disposed in the first well region. A gate electrode is disposed on the first and second well regions.

The present disclosure relates to a multilayer semiconductor-on-insulator structure, comprising, successively from a rear face toward a front face of the structure: a semiconductor carrier substrate with high electrical resistivity, whose electrical resistivity is between 500 .Math.cm and 30 k.Math.cm, a first electrically insulating layer, an intermediate layer, a second electrically insulating layer, which has a thickness less than that of the first electrically insulating layer, an active semiconductor layer, the multilayer structure comprises: at least one FD-SOI region, in which the intermediate layer is an intermediate first semiconductor layer, at least one RF-SOI region, adjacent to the FD-SOI region, in which the intermediate layer is a third electrically insulating layer, the RF-SOI region comprising at least one radiofrequency component plumb with the third electrically insulating layer.

A second gate electrode is adjacent, in a Y direction, to a first tip of a semiconductor layer in a first active region such that a protruding distance of a second tip of the second gate electrode protruded, in a X direction, from the semiconductor layer in the first active region is greater than or equal to 0. Also, the first tip of the semiconductor layer in the first active region is covered with a second sidewall spacer. Further, a first epitaxial layer and the second gate electrode are electrically connected to each other via a first shared contact plug formed so as to across the first epitaxial layer, the second sidewall spacer and the second gate electrode.

A method of making a silicon-on-insulator (SOI) device from a bulk silicon substrate and an SOI device are disclosed. In the method, a stack of a heteroepitaxial layer and a silicon epitaxial layer are formed on a bulk silicon substrate, and a first photolithography process is performed on the stack to form a first trench exposing the bulk silicon substrate. The first trench is filled with a first isolation dielectric, and a second photolithography process is performed on the stack to form a second trench. The first isolation dielectric and the second trench isolate the stack. Subsequently, the heteroepitaxial layer is removed from the stack, forming at least one cavity. Moreover, the at least one cavity is filled with a buried oxide layer. The buried oxide layer and the silicon epitaxial layer overlying the buried oxide layer form SOI substrate structures. SOI devices are formed on the SOI substrate structures.

Techniques for joining dissimilar materials in microelectronics are provided. Example techniques direct-bond dissimilar materials at an ambient room temperature, using a thin oxide, carbide, nitride, carbonitride, or oxynitride intermediary with a thickness between 100-1000 nanometers. The intermediary may comprise silicon. The dissimilar materials may have significantly different coefficients of thermal expansion (CTEs) and/or significantly different crystal-lattice unit cell geometries or dimensions, conventionally resulting in too much strain to make direct-bonding feasible. A curing period at ambient room temperature after the direct bonding of dissimilar materials allows direct bonds to strengthen by over 200%. A relatively low temperature anneal applied slowly at a rate of 1 C. temperature increase per minute, or less, further strengthens and consolidates the direct bonds. The example techniques can direct-bond lithium tantalate LiTaO.sub.3 to various conventional substrates in a process for making various novel optical and acoustic devices.

An SOI wafer contains a compressively stressed buried insulator structure. In one example, the stressed buried insulator (BOX) may be formed on a host wafer by forming silicon oxide, silicon nitride and silicon oxide layers so that the silicon nitride layer is compressively stressed. Wafer bonding provides the surface silicon layer over the stressed insulator layer. Preferred implementations of the invention form MOS transistors by etching isolation trenches into a preferred SOI substrate having a stressed BOX structure to define transistor active areas on the surface of the SOI substrate. Most preferably the trenches are formed deep enough to penetrate through the stressed BOX structure and some distance into the underlying silicon portion of the substrate. The overlying silicon active regions will have tensile stress induced due to elastic edge relaxation.