Abstract: A semiconductor structure comprises a first portion of an interconnect line comprising a first conducting line segment and a second conducting line segment separated by an isolating layer, and a second portion of the interconnect line comprising a third conducting line segment vertically stacked over at least a portion of the first conducting line segment and at least a portion of the second conducting line segment.

Abstract: A method is presented forming a fully-aligned via (FAV) and airgaps within a semiconductor device. The method includes forming a plurality of copper (Cu) trenches within an insulating layer, forming a plurality of ILD regions over exposed portions of the insulating layer, selectively removing a first section of the ILD regions in an airgap region, and maintaining a second section of the ILD regions in a non-airgap region. The method further includes forming airgaps in the airgap region and forming a via in the non-airgap region contacting a Cu trench of the plurality of Cu trenches.

Abstract: A microelectronic structure including a plurality of electronic devices. A plurality of frontside contacts, where each of the plurality of frontside contacts is connected to a frontside of one of the plurality electronic devices, respectively. Each of the plurality of frontside contacts is a same first electric potential. A plurality of backside contacts, where the plurality of backside contacts is connected to a backside of one of the plurality of electronic devices, respectively. Each of the plurality of backside contacts is a same second electrical potential, where the first electrical potential is different than the second electrical potential.

Abstract: Embodiments of the present invention are directed to processing methods and resulting structures having hybrid backside dielectrics. In a non-limiting embodiment of the invention, a front end of line structure is formed and a back end of line structure is formed on a first surface of the front end of line structure. A backside power delivery network is formed on a second surface of the front end of line structure opposite the first surface. The backside power delivery network includes a first set of interconnect lines in a first metallization level, a second set of interconnect lines in the first metallization level, and a hybrid backside dielectric structure. The hybrid backside dielectric structure includes a first dielectric material and a second dielectric material. The first set of interconnect lines are embedded in the first dielectric material and the second set of interconnect lines are embedded in the second dielectric material.

Abstract: A dual structure buried rail includes an upper rail and a lower rail. The upper rail may be inset relative to the lower rail. In other words, the lower rail may be wider than the upper rail, and/or the lower rail may have a larger geometrical volume than the upper rail. The upper rail may be located at a boundary of, and/or directly next to, an active device region and the lower rail may extend directly underneath at least a portion of the active device region. The lower rail may extend the entire length of the upper rail. The dual structure buried rail may reduce buried rail resistance which may reduce voltage drop thereacross and provide for improved semiconductor device and/or active device region performance. The dual structure buried rail may provide power potential delivery, provide potential sinking, or the like, to one or more active device region(s).

Abstract: Devices and methods of forming the same include a first conductive line having a top surface at a first height above an underlying layer. A second conductive line, parallel to the first conductive line, has a second height above the underlying layer that is greater than the first height. A first interlayer dielectric layer, between the first conductive line and the second conductive line, has a top surface at a third height above the underlying layer that is greater than the first height and that is less than the second height.

Abstract: A semiconductor interconnect structure comprises a substrate, a plurality of metal lines disposed relative to the substrate and a plurality of first and second caps disposed on the metal lines wherein the first caps comprise a first dielectric material and the second caps comprise a second dielectric material different from the first dielectric material.

Abstract: Low capacitance and high reliability interconnect structures and methods of manufacture are disclosed. The method includes forming a copper based interconnect structure in an opening of a dielectric material. The method further includes forming a capping layer on the copper based interconnect structure. The method further includes oxidizing the capping layer and any residual material formed on a surface of the dielectric material. The method further includes forming a barrier layer on the capping layer by outdiffusing a material from the copper based interconnect structure to a surface of the capping layer. The method further includes removing the residual material, while the barrier layer on the surface of the capping layer protects the capping layer.

Abstract: A semiconductor device includes a semiconductor substrate having a top surface and a bottom surface. An electronic device is integrated into the top surface of the semiconductor substrate. A conductive power rail is positioned intermediate the top surface and the bottom surface of the semiconductor substrate. The conductive power rail is configured to conduct power to the electronic device.

Abstract: The semiconductor device includes a first metal layer, a second metal layer, a metal plane, a third dielectric layer and a fourth dielectric layer. The first metal layer comprises a first dielectric layer with a first plurality of signal track and a first plurality of power rails. The second metal layer comprises a second dielectric layer with a second plurality of signal tracks and a second plurality of power rails. The metal plane is between the first metal layer and the second metal layer. The third dielectric layer is between the first metal layer and the metal plane. The fourth dielectric layer is between the second metal layer and the metal plane.

Abstract: A semiconductor component includes an area of dielectric material extending below an uppermost surface of a substrate. The semiconductor component further includes a trench formed so as to extend from above the uppermost surface of the substrate into the area of dielectric material. The semiconductor component further includes a non-metal liner coating interior surfaces of the trench. The semiconductor component further includes a metal liner coating interior surfaces of the non-metal liner. The semiconductor component further includes a power rail formed in the trench in direct contact with at least one of the metal liner or the non-metal liner such that the power rail extends into the area of dielectric material and above the uppermost surface of the substrate.

Abstract: A skip-level through-silicon via structure is provided that enables low resistance via connection for backside power distribution by skipping one or more intermediate backside metal layers. The skip-level through-silicon via structure can enable a greater design flexibility for power grid. The skip-level through-silicon via structure has a large size that provides lower through-silicon via resistance as compared with conventional through-silicon via structures.

Abstract: Embodiments disclosed herein include a semiconductor structure. The semiconductor structure may include a first power plane electrically connected to a first plurality of via-to-backside power planes (VBPPs), a second power plane, and a plurality of pass through vias electrically connecting the second power plane to a second plurality of VBPPs, wherein the plurality of pass through vias pass through the first power plane.

Abstract: Low capacitance and high reliability interconnect structures and methods of manufacture are disclosed. The method includes forming a copper based interconnect structure in an opening of a dielectric material. The method further includes forming a capping layer on the copper based interconnect structure. The method further includes oxidizing the capping layer and any residual material formed on a surface of the dielectric material. The method further includes forming a barrier layer on the capping layer by outdiffusing a material from the copper based interconnect structure to a surface of the capping layer. The method further includes removing the residual material, while the barrier layer on the surface of the capping layer protects the capping layer.

Abstract: A semiconductor structure with one or more backside metal layers that include a plurality of portions of a floating metal layer separated by dielectric material from one or more power and ground lines in the backside metal layer. The height of each of the plurality of portions of the floating metal layer in each of the one or more backside metal layers and the distance between adjacent portions of the plurality of portions of the floating metal layer in each of the one or more backside metal layer correlates to the capacitance of each of the one or more backside metal layers.

Abstract: A method of fabricating a dielectric film includes depositing a first precursor on a substrate. The first precursor includes a cyclic carbosiloxane group comprising a six-membered ring. The method also includes depositing a second precursor on the substrate. The first precursor and the second precursor form a preliminary film on the substrate, and the second precursor includes silicon, carbon, and hydrogen. The method further includes exposing the preliminary film to energy from an energy source to form a porous dielectric film.

Abstract: A semiconductor structure including a metal layer including a Vdd metal line, a Vss metal line, signal lines and a high-k dielectric between the Vdd and Vss metal lines, and a dielectric surrounding the signal lines. A semiconductor structure including a metal layer including a Vdd metal line, a Vss metal line, signal lines, and a high-k dielectric between the Vdd metal line and the Vss metal line, where a width between the Vdd metal line and the Vss metal line is less than a width between each of the signal lines. A method including forming a bulk metal layer on a structure, removing portions of the bulk metal layer, remaining portions of the bulk metal layer form metal lines, the metal lines include a Vdd metal line, a Vss metal line and signal lines, and forming a high-k dielectric between the Vdd metal line and the Vss metal line.

Abstract: One or more systems, devices and/or methods provided herein relate to a circuit device having a modular or selectively designed interconnect structure with a plurality of conformal features. In the semiconductor realm, such achievements can allow for fabrication of a device with sub 18 nanometer (nm) or lesser pitch between adjacent and/or parallel lines of the interconnect structure. A device can comprise a semiconductor device having an interconnect structure having a first set of parallel lines and a second set of parallel lines, where the lines of the first set can be arranged in a transverse direction to the lines of the second set. The lines of the first set can be disposed orthogonally to the lines of the second set. The first second sets of lines can comprise first and second rounded jogs that are conformal to one another and which connect the first set of lines to the second set of lines.

Abstract: A method is presented forming a fully-aligned via (FAV) and airgaps within a semiconductor device. The method includes forming a plurality of copper (Cu) trenches within an insulating layer, forming a plurality of ILD regions over exposed portions of the insulating layer, selectively removing a first section of the ILD regions in an airgap region, and maintaining a second section of the ILD regions in a non-airgap region. The method further includes forming airgaps in the airgap region and forming a via in the non-airgap region contacting a Cu trench of the plurality of Cu trenches.

Abstract: A method is presented for selective deposition on metals using porous low-k materials. The method includes forming alternating layers of a porous dielectric material and a first conductive material, forming a surface aligned monolayer (SAM) over the first conductive material, depositing hydroxamic acid (HA) material over the porous dielectric material, growing an oxide material over the first conductive material, removing the SAM, depositing a dielectric layer adjacent the oxide material, and replacing the oxide material with a second conductive material defining a bottom electrode.