In some embodiments, the present disclosure relates to an integrated chip having an inter-tier interconnecting structure having horizontal components, which is arranged within a semiconductor substrate and configured to electrically couple a first device tier to a second device tier. The integrated chip has a first device tier with a first semiconductor substrate. A first inter-tier interconnecting structure is disposed inside the first semiconductor substrate. The first inter-tier interconnecting structure has a first segment extending in a first direction and a second segment protruding outward from a sidewall of the first segment in a second direction substantially perpendicular to the first direction. A second device tier is electrically coupled to the first device tier by the first inter-tier interconnecting structure.

A semiconductor device structure may include a substrate having a substrate base comprising a first dopant type; a semiconductor layer disposed on a surface of the substrate base, the semiconductor layer comprising a second dopant type and having an upper surface; and a semiconductor plug assembly comprising a semiconductor plug disposed within the semiconductor layer, the semiconductor plug extending from an upper surface of the semiconductor layer and having a depth at least equal to a thickness of the semiconductor layer, the semiconductor plug having a first boundary, the first boundary formed within the semiconductor layer, and having a second boundary, the second boundary formed within the semiconductor layer and disposed opposite the first boundary, wherein the first boundary and second boundary extend perpendicularly to the surface of the substrate base.

Structures and methods for reducing process charging damages are disclosed. In one example, a silicon-on-insulator (SOI) structure is disclosed. The SOI structure includes: a substrate, a polysilicon region and an etch stop layer. The substrate includes: a handle layer, an insulation layer arranged over the handle layer, and a buried layer arranged over the insulation layer. The polysilicon region extends downward from an upper surface of the buried layer and terminates in the handle layer. The etch stop layer is located on the substrate. The etch stop layer is in contact with both the substrate and the polysilicon region.

Some embodiments include a method of forming an arrangement. A first tier is formed to include CMOS circuitry. A second tier is formed to include an assembly which has first and second sets of memory cells on opposing sides of a coupling region. A support material is adjacent the first and second sets of the memory cells, and an intervening material is adjacent the support material. The support material has a different composition than the intervening material. A conductive interconnect extends through the intervening material. An upper surface of the assembly is polished to reduce an overall height of the assembly. The support material provides support during the polishing to protect the memory cells from being eroded during the polishing. The conductive interconnect of the second tier is coupled with the CMOS circuitry of the first tier. Some embodiments include multitier arrangements.

Systems, methods and apparatus for coexistence of high voltage and low voltage devices and circuits on a same integrated circuit fabricated in silicon-on-insulator (SOI) technology are described. In particular, techniques for mitigating back gate effects are described, including using of resistive and/or capacitive couplings to control surface potentials at regions of a substrate used for the SOI fabrication proximate the high voltage and low voltage devices and circuits. In one case, an N-type implant is used to provide a high potential differential with respect to a substrate potential.

Techniques to form wrap-around contacts in a stacked transistor architecture. An example includes a first source or drain region and a second source or drain region spaced from and over the first source or drain region. A conductive contact is on a top surface of the second source or drain and extends down one or more side surfaces of the second source or drain region such that the conductive contact is laterally adjacent to a bottom surface of the second source or drain region. In some cases, the conductive contact is also on a top surface of the first source or drain region, and/or extends down a side surface of the first source or drain region. In some cases, a second conductive contact is on a bottom surface of the first source or drain region, and may extend up a side surface the first source or drain region.

An integrated circuit structure includes a first sub-fin, a second sub-fin laterally spaced from the first sub-fin, a first transistor device over the first sub-fin and having a first contact, a second transistor device over the second sub-fin and having a second contact, and a continuous and monolithic body of conductive material extending vertically between the first and second transistor devices and the first and second sub-fins. The body of conductive material has (i) an upper portion between the first and second transistor devices and (ii) a lower portion between the first and second sub-fins. A continuous conformal layer extends along a sidewall of the lower portion of the body and a sidewall of the upper portion of the body. The integrated circuit structure further comprises a conductive interconnect feature connecting the upper portion of the body to at least one of the first and second contacts.

An IC structure includes a source epitaxial structure, a drain epitaxial structure, a first silicide region, a second silicide region, a source contact, a backside via rail, a drain contact, and a front-side interconnection structure. The first silicide region is on a front-side surface, a first sidewall of the source epitaxial structure, and a second sidewall of the source epitaxial structure. The second silicide region is on a front-side surface of the drain epitaxial structure. The source contact is in contact with the first silicide region and has a protrusion extending past a backside surface of the source epitaxial structure. The backside via rail is in contact with the protrusion of the source contact. The drain contact is in contact with the second silicide region. The front-side interconnection structure is on a front-side surface of the source contact and a front-side surface of the drain contact.

A method of manufacturing a semiconductor structure includes: forming a trench in a back side of a substrate; depositing a dopant on surfaces of the trench; forming a shallow trench isolation (STI) structure in a top side of the substrate opposite the trench; forming a deep well in the substrate; out-diffusing the dopant into the deep well and the substrate; forming an N-well and a P-well in the substrate; and filling the trench with a conductive material.

IC devices including semiconductor devices isolated by BSRs are disclosed. An example IC device includes a first and a second semiconductor devices, a support structure, and a BSR. The BSR defines boundaries of a first and second section in the support structure. At least a portion of the first semiconductor device is in the first section, and at least a portion of the second semiconductor device is in the second section. The first semiconductor device is isolated from the second semiconductor device by the BSR. Signals from the first semiconductor device would not be transmitted to the second semiconductor device through the support structure. The BSR may be connected to a TSV or be biased. The IC device may include additional BSRs to isolate the first and second semiconductor devices. An BSR may be a power rail used for delivering power.