An integrated circuit (IC) chip is provided. In one aspect, a semiconductor substrate includes active devices on its front surface and power delivery tracks on its back surface. The active devices are powered through mutually parallel buried power rails, with the power delivery tracks running transversely with respect to the power rails, and connected to the power rails by a plurality of Through Semiconductor Via connections, which run from the power rails to the back of the substrate. The TSVs are elongate slit-shaped TSVs aligned to the power rails and arranged in a staggered pattern, so that any one of the power delivery tracks is connected to a first row of mutually parallel TSVs, and any power delivery track directly adjacent to the power delivery track is connected to another row of TSVs which are staggered relative to the TSVs of the first row. A method of producing an IC chip includes producing the slit-shaped TSVs before the buried power rails.

Disclosed are a semiconductor device and a method of fabricating the same. The semiconductor device may include a substrate having a groove therein extending in a first direction, a gate insulating layer in the groove, a first conductive pattern in the groove and on the gate insulating layer, and a word line capping pattern in the groove and on the first conductive pattern. The first conductive pattern may include a first material and may include a first conductive portion adjacent to the word line capping pattern and a second conductive portion adjacent to a bottom end of the groove. A largest dimension of a grain of the first material of the first conductive portion may be equal to or larger than that of the first material of the second conductive portion.

A semiconductor structure includes a field effect transistor (FET) having a source/drain, a contact in contact with the source/drain, and a buried power rail including a conductive material, wherein the buried power rail is in contact with the contact, wherein a first portion of the buried power rail closest to the contact has a first thickness, and wherein a second portion of the buried power rail has a second thickness such that the first thickness is less than the second thickness.

A method for producing a 3D memory device, the method including: providing a first level including a first single crystal layer and control circuits; forming at least one second level above the first level; performing a first etch step including etching holes within the second level; forming at least one third level above the at least one second level; performing a second etch step including etching holes within the third level; and performing additional processing steps to form a plurality of first memory cells within the second level and a plurality of second memory cells within the third level, where each of the first memory cells include one first transistor, where each of the second memory cells include one second transistor, where at least one of the first or second transistors has a channel, a source, and a drain having a same doping type.

A method for producing a 3D memory device including: providing a first level including a single crystal layer and control circuits, where the control circuits include a plurality of first transistors; forming at least one second level above the first level; performing a first etch step including etching holes within the second level; performing processing steps to form a plurality of first memory cells within the second level, where each of the first memory cells include one of a plurality of second transistors, where the control circuits include memory peripheral circuits, where at least one first memory cell is at least partially atop a portion of the memory peripheral circuits, and where fabrication processing of the first transistors accounts for a temperature and time associated with processing the second level and the plurality of second transistors by adjusting a process thermal budget of the first level accordingly.

A method of forming a semiconductor device includes forming a wafer having an ion-implanted silicon layer, wherein the ion-implanted silicon layer is disposed between a first insulator layer and a second insulator layer inside the wafer; forming an active region over the ion-implanted silicon layer; forming an active device in the active region; and forming a conductive via to couple the ion-implanted silicon layer and the active device.

A 3D semiconductor device, the device including: a first level including a first single crystal layer, the first level including first transistors, where the first transistors each include a single crystal channel; first metal layers interconnecting at least the first transistors; a second metal layer overlaying the first metal layers; and a second level including a second single crystal layer, the second level including second transistors, where the second level overlays the first level, where the second transistors each include at least two side-gates, where the second level is bonded to the first level, and where the bonded includes oxide to oxide bonds.

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.

This application provides a semiconductor device and a preparation method thereof. A second region of the semiconductor device has a through gallium nitride via (TGV), and the semiconductor device includes a substrate, and an epitaxial layer, a first dielectric layer, a first metal layer, a second dielectric layer, a protective layer, and a second metal layer that are sequentially on the substrate. The second dielectric layer has a through via that penetrates through the second dielectric layer to connect the first metal layer and the protective layer, and a connecting material is in the through via to form a connecting piece. In addition, the TGV penetrates through the protective layer, the second dielectric layer, the first dielectric layer, and the epitaxial layer to the substrate. The second metal layer is on the protective layer and an inner wall of the TGV and is in contact with the substrate.

A semiconductor structure includes a power distribution network including a first buried power rail, a power wire, and a first buried via electrically interconnecting the first buried power rail and the power wire. Each of the first buried power rail, the power wire, and the first buried via have a liner on a corresponding bottom surface thereof and sidewalls thereof. The structure also includes a dielectric layer outward of the power distribution network; a first field effect transistor outward of the dielectric layer; a first via trench contact electrically interconnecting a source/drain region of the transistor to the first buried power rail; a first outer wire outward of the first field effect transistor; and an electrical path electrically interconnecting the first outer wire with the power wire.