Embodiments disclosed herein include a semiconductor structure. The semiconductor structure may include a first transistor device on a substrate, a second transistor device on the substrate, and a power rail between the first transistor device and the second transistor device. The power rail may include a first section with a first critical dimension (CD), a second section with a second CD, and a third section with a third CD.

A method including forming an oxide layer on a first substrate and forming a second substrate on the oxide layer. Doping a first section of the second substrate while not doping a second section of the second substrate. Forming a first nano device on the second section of the second substrate and forming a second nano device on first section of the second substrate. Flipping the first substrate over to allow for backside processing of the substrate and forming at least one backside contact connected to the first nano device while backside contacts are not formed or connected to the second nano device.

A semiconductor structure includes a stacked device structure having a first field-effect transistor having a first source/drain region, and a second field-effect transistor vertically stacked above the first field-effect transistor, the second field-effect transistor having a second source/drain region and a gate region having first sidewall spacers. The stacked device structure further includes a frontside source/drain contact disposed on a first portion of a sidewall and a top surface of the second source/drain region, a first metal via connected to the frontside source/drain contact and to a first backside power line, and second sidewall spacers disposed on a first portion of the first metal via. The first sidewall spacers comprise a first dielectric material and the second sidewall spacers comprise a second dielectric material different than the first dielectric material.

A semiconductor device includes: a channel having layers of silicon separated from each other; a metal gate in contact with the layers of silicon; source/drain regions adjacent to the metal gate; a frontside power rail extending through the layers of silicon; a dielectric separating the frontside power rail from the metal gate; a via-connect buried power rail extending through the dielectric and coupling the frontside power rail to the source/drain regions; and a backside power rail coupled to the frontside power rail. The layers of silicon are wrapped on three sides by the metal gate.

A microelectronic structure including a nanosheet transistor that includes a source/drain. A frontside contact that includes a first section located on the frontside of the source/drain and a via section that extends to the backside of the nanosheet transistor. A shallow isolation layer located around a portion of the via section the first frontside contact. A backside metal line located on a backside surface of the via section and located on a backside surface of the shallow trench isolation layer. A dielectric liner located along a sidewall of the backside metal line and located along a bottom surface of the backside metal line.

A method of forming a semiconductor device is provided. The method includes forming an etch stop layer on a substrate having a first thickness, forming an epitaxial layer on the etch stop layer, and forming a wafer device on the epitaxial layer. The wafer device is bonded to a bonding wafer using hybrid bonding. The substrate is then ground to a second thickness less than the first thickness and planarized to a third thickness less than the second thickness. A mask layer is deposited on a bottom surface of the etch stop layer, and at least one via opening is formed in the mask layer. The etch stop layer is selectively removed, and the mask layer is removed to expose the substrate at the third thickness.

A method is described. The method includes creating a partial through-substrate via (TSV) plug in a front side of a wafer, the partial TSV having a front side and a back side. The back side of the partial TSV extending toward a front side of a substrate but not into a bulk of the substrate. A cavity is etched in a back side of the wafer that exposes the partial TSV plug. An insulator is applied to the etched back side of the wafer. A portion of the partial TSV plug is exposed by removing a portion of the insulator. A conductive material is deposited to connect the exposed, partial TSV plug to a surface on the back side of the wafer.

In integrated circuit packages, a coaxial pair of signals are routed through a plated through hole between circuitry on one face of the core substrate material with circuitry on an opposing face of the core substrate material. Provided are methods and apparatuses where signals are routed within a concentric reference conductor within traditional package substrates. Methods for forming a hole in the core substrate material through which the coaxial pair of signals is passed on a fine pitch.

Disclosed are a silicon wafer and a method for filling a silicon via thereof, and belong to the field of superconducting quantum technologies. The method includes: obtaining a silicon wafer including at least one silicon via; providing a superconducting material on at least one side of the silicon wafer, the at least one side comprising a side where an opening of the silicon via is located; and heating and pressurizing the superconducting material to fill the superconducting material into the silicon via.

An anti-diffusion substrate structure includes a substrate, a substrate circuit layer, and a chip. The substrate has multiple through holes. Within each of the through holes includes a first metal layer and an anti-diffusion layer plated on the first metal layer. The anti-diffusion layer is an Electroless Palladium Immersion Gold (EPIG) layer or an Electroless Nickel Electroless Palladium Immersion Gold (ENEPIG) layer. The substrate circuit layer is mounted on the substrate and extended on the anti-diffusion layer within each of the through holes. The substrate circuit layer is made of a second metal layer, and a composition of the second metal layer is different from a composition of the first metal layer. The chip is electrically connected to the substrate circuit layer. The anti-diffusion layer is able to better prevent material of the first metal layer from migrating or diffusing to the second metal layer.