In some embodiments, the present disclosure relates to an integrated chip that includes a semiconductor device, a polysilicon isolation structure, and a first and second insulator liner. The semiconductor device is disposed on a frontside of a substrate. The polysilicon isolation structure continuously surrounds the semiconductor device and extends from the frontside of the substrate towards a backside of the substrate. The first insulator liner and second insulator liner respectively surround a first outermost sidewall and a second outermost sidewall of the polysilicon isolation structure. The substrate includes a monocrystalline facet arranged between the first and second insulator liners. A top of the monocrystalline facet is above bottommost surfaces of the polysilicon isolation structure, the first insulator liner, and the second insulator liner.

A method includes forming a first multilayer interconnection structure over a carrier substrate. A first interlayer dielectric (ILD) layer is deposited over the first multilayer interconnection structure. A first source/drain contact is formed in the first ILD layer. After forming the first source/drain contact, a semiconductive layer is formed over the first source/drain contact and the first ILD layer. The semiconductive layer is patterned to form a semiconductor fin over the first source/drain contact. A gate structure is formed across the semiconductor fin. The semiconductor fin is patterned to form a first recess and a second recess in the semiconductor fin, such that the first recess exposes the first source/drain contact. First and second source/drain epitaxial structures are respectively formed in the first and second recesses of the semiconductor fin such that the first source/drain epitaxial structure is electrically connected to the first source/drain contact.

Semiconductor structures are disclosed which comprise semiconductor devices having buried power rails. In one example, a semiconductor structure comprises a plurality of semiconductor devices. Each of the semiconductor devices is isolated from an adjacent semiconductor device by a dielectric layer. The semiconductor structure further comprises a first diffusion break extending across the plurality of semiconductor devices, a second diffusion break extending across the plurality of semiconductor devices and a plurality of gates extending across the plurality of semiconductor devices. The gates are disposed between the first diffusion break and the second diffusion break. Each semiconductor device comprises a power rail extending between the first diffusion break and the second diffusion break under the plurality of gates.

A 3D semiconductor device, the device including: a first level including a plurality of first metal layers; a second level, where the second level overlays the first level, where the second level includes at least one single crystal silicon layer, where the second level includes a plurality of transistors, where each transistor of the plurality of transistors includes a single crystal channel, where the second level includes a plurality of second metal layers, where the plurality of second metal layers include interconnections between the transistors of the plurality of transistors, where the second level is overlaid by a first isolation layer; and a connective path between the plurality of transistors and the plurality of first metal layers, where the connective path includes a via disposed through at least the single crystal silicon layer, and where at least one of the plurality of transistors includes a gate all around structure.

A semiconductor structure comprises a substrate having a first side and a second side opposite the first side, and a gate for at least one transistor device disposed above the first side of the substrate. The structure may further include a buried power rail at least partially disposed in the substrate and a gate tie-down contact connecting the gate to the buried power rail from the second side of the substrate. The structure may further or alternatively include one or more source/drain regions disposed over the first side of the substrate, and a gate contact connecting to a portion of the gate from the second side of the substrate, the portion of the gate being adjacent to at least one of the one or more source/drain regions.

Embodiments of the present invention are directed to fabrication methods and resulting structures that provide buried contacts in the fin-to-fin space of vertical transport field effect transistors (VFETs) that connect the bottom S/D of the transistors to a buried power rail. In a non-limiting embodiment of the invention, a buried power rail is encapsulated in a buried oxide layer of a first wafer. First and second semiconductor fins are formed on a second wafer. The first wafer to the second wafer and a surface of the buried power rail in a fin-to-fin space is exposed. A buried via is formed on the exposed surface of the buried power rail. The buried via electrically couples the buried power rail to a bottom source or drain region of the first semiconductor fin.

The present disclosure relates to a semiconductor structure and a method for manufacturing the same. The method includes: providing a base, at least one shallow trench isolating structure being formed in the base and several active regions arranged at an interval being isolated by the shallow trench isolating structure in the base; forming a first trench in the base, a part of the active regions being exposed in the first trench; forming a first conducting structure in the first trench; forming a first dielectric layer on the base; forming a second trench in the first dielectric layer, the first conducting structure being exposed in the second trench and a width of a top of the second trench being greater than a width of a top of the first trench; and forming a second conducting structure in the second trench.

An illustrative device disclosed herein includes a doped well region and a conductive well tap conductively coupled to the doped well region, the conductive well tap including first and second opposing sidewall surfaces. In this example the device also includes a first sidewall spacer that has a first vertical height positioned around the conductive well tap and a second sidewall spacer positioned adjacent the first sidewall spacer along the first and second opposing sidewall surfaces of the conductive well tap, wherein the second sidewall spacer has a second vertical height that is less than the first vertical height.

A method for producing a 3D semiconductor device including: providing a first level including a first single crystal layer; forming peripheral circuitry in and/or on the first level, and includes first single crystal transistors; forming a first metal layer on top of the first level; forming a second metal layer on top of the first metal layer; forming second level disposed on top of the second metal layer; performing a first lithography step; forming a third level on top of the second level; performing a second lithography step; processing steps to form first memory cells within the second level and second memory cells within the third level, where the plurality of first memory cells include at least one second transistor, and the plurality of second memory cells include at least one third transistor; and deposit a gate electrode for second and third transistors simultaneously.

An electronic device, and method of producing an electronic device, are disclosed. The electronic device comprises a diamond substrate 10. Within the substrate 10 is an electrode 12, known as a ‘buried electrode’. A first surface 14 of the substrate 10 is provided with a conductive contact region 16. The electrode 12 is electrically connected to the contact region 16 by a conductive pillar 18. The electrode, conductive pillar, and contact region comprise modified portions of the diamond substrate, for example comprising at least one of graphitic carbon, amorphous carbon, and a combination of SP2 and SP3 phases of carbon, formed from a portion of diamond substrate.