In described examples, a device includes a semiconductor substrate; a buried layer; and a trench with inner walls extending from the buried layer to a surface of the semiconductor substrate, the trench having sidewalls, a bottom wall, a barrier layer including a titanium (Ti) layer covering the sidewalls and the bottom wall, and a filler including more than one layer of conductor material formed on the barrier layer.

The present application discloses a method for fabricating a semiconductor device with liners. The method includes providing a substrate having a first surface and a second surface opposite to the first surface, inwardly forming a trench on the first surface of the substrate, forming a plurality of liners positioned on side surfaces of the trench, forming a first insulating segment filling the trench, and removing part of the substrate from the second surface to expose the first insulating segment and the plurality of liners.

The present disclosure relates to isolation structures for semiconductor devices and, more particularly, to dual trench isolation structures having a deep trench and a shallow trench for electrically isolating integrated circuit (IC) components formed on a semiconductor substrate. The semiconductor isolation structure of the present disclosure includes a semiconductor substrate, a shallow trench isolation (STI) disposed over the semiconductor substrate, a deep trench isolation (DTI) with sidewalls extending from a bottom surface of the STI and terminating in the semiconductor substrate, a multilayer dielectric lining disposed on the sidewalls of the DTI, the multilayer dielectric lining including an etch stop layer positioned between inner and outer dielectric liners, and a filler material disposed within the DTI.

Embodiments of the disclosure provide an integrated circuit (IC) structure, including a semiconductor-based isolation structure on a substrate. A shallow trench isolation (STI) structure may be positioned on the semiconductor-based isolation structure. An active semiconductor region is on the substrate and adjacent each of the semiconductor-based isolation structure and the STI structure. The active semiconductor region includes a doped semiconductor material. At least one device on the active semiconductor region may be horizontally distal to the STI structure.

A method for forming a deep trench isolation structure for a CMOS image sensor includes providing a trench that extends from a first side toward a second side of a semiconductor substrate. The trench has an opening on the first side and a bottom and sides. A conformal layer of B-doped oxide is deposited on the bottom and sides of the trench and is less than half a width of the trench leaving a depthwise recess in the trench. A second material is deposited on the conformal layer of B-doped oxide in the trench filling the recess in the trench to the first side. The conformal layer of B-doped oxide is annealed driving boron from the conformal layer of B-doped oxide to the semiconductor substrate forming a B-doped region as a passivation layer juxtaposed next to the conformal layer of B-doped oxide having negative fixed charges.

The present disclosure includes semiconductor structures and methods of forming semiconductor structures for trench isolation interfaces. An example semiconductor structure includes a semiconductor substrate having a shallow trench isolation (STI) structure with a trench formed therein. A material in the trench forms a charged interface by interaction with the semiconductor substrate of the STI structure. The formed charged interface raises a parasitic threshold of the STI structure.

A semiconductor structure and a forming method thereof are provided. One form of the forming method includes: providing a base, where a well region and a drift region adjacent to the well region are formed in the base; forming a trench in the drift region; forming a diffusion barrier layer in the trench; after the diffusion barrier layer is formed, forming a gate structure on the base at a junction between the well region and the drift region, where the gate structure is located on a side of the diffusion barrier layer near the well region; and forming a source region in the well region on one side of the gate structure, and forming a drain region in the drift region on the other side of the gate structure, where the drain region is located on a side of the diffusion barrier layer in the drift region away from the well region. In embodiments and implementations of the present disclosure, during the operation of the semiconductor structure, under the barrier action of the diffusion barrier layer, doping ions in the drain region do not easily diffuse into the channel region below the gate structure, which makes a depletion layer of the source region and the drain region on two sides of the gate structure not easily expand, thereby being beneficial to alleviate the short-channel effect, and further improving the electrical performance of the semiconductor structure.

A semiconductor device includes etch stop films formed on the first gate electrode, the first source region, the first drain region, and the shallow trench isolation regions, respectively. First interlayer insulating films are formed on the etch stop film, respectively. Deep trenches are formed in the substrate between adjacent ones of the first interlayer insulating films to overlap the shallow trench isolation regions. Sidewall insulating films are formed in the deep trenches, respectively. A gap-fill insulating film is formed on the sidewall insulating film. A second interlayer insulating film is formed on the gap-fill insulating film. A top surface of the second interlayer insulating film is substantially planar and a bottom surface of the second interlayer insulating film is undulating.

A process for forming a predetermined separation zone inside a donor substrate, in particular, to be used in a process of transferring a layer onto a carrier substrate comprises an implantation step that is carried out such that the implantation dose in a zone of the edge of the donor substrate is lower than the implantation dose in a central zone of the donor substrate to limit the formation of particles during thermal annealing. The present disclosure also relates to a donor substrate for a process of transferring a thin layer onto a carrier substrate produced by means of the process described above. The present disclosure also relates to a device for limiting an implantation region to a zone of the edge of a donor substrate.

A semiconductor layer is etched into a plurality of fin structures. A first nitridation process is performed to side surfaces of the fin structures. The first nitridation process forms a first oxynitride layer at the side surfaces of the fin structures. A liner oxide layer is formed on the first oxynitride layer. An isolation structure is formed around the fin structures after the forming of the liner oxide layer.