Abstract: Some implementations described herein provide a semiconductor device and methods of formation. The semiconductor device includes a transistor structure that is electrically connected to a metal layer. Described techniques include forming an interconnect structure that electrically connects the metal layer to a backside power rail structure. The techniques include forming a first portion of the interconnect structure using a layer of silicon germanium as an etch stop and, after removal of the layer of the silicon germanium, forming a second portion of the interconnect structure.

Abstract: A method is provided for forming a memory device on a backside portion of a wafer substrate. In one step, a circuit device is formed on a frontside portion of the wafer substrate. In one step, the wafer substrate is etched to form a substrate indentation that exposes a portion of a circuit device. In one step, a memory device is formed, at least in part, in the substrate indentation.

Abstract: A semiconductor device includes a channel layer, an interfacial layer, a gate dielectric layer, a gate electrode, dipole elements, and additional elements. The interfacial layer is disposed on the channel layer, and includes an insulating material. The gate dielectric layer is disposed over the interfacial layer such that the channel layer is separated from the gate dielectric layer by the interfacial layer. The gate electrode is disposed on the gate dielectric layer. The dipole elements are present in at least one of the interfacial layer and the gate dielectric layer in a predetermined amount such that the semiconductor device has a predetermined threshold voltage. The additional elements are located at a region where the dipole elements are present so as to reduce interfacial defects caused by the dipole elements. The additional elements are different from the dipole elements. Methods for manufacturing the semiconductor device are also disclosed.

Abstract: A ferroelectric memory cell (FeRAM) is disclosed that includes an active device (e.g., a transistor) and a passive device (e.g., a ferroelectric capacitor) integrated in a substrate. The transistor and its gate contacts are formed on a front side of the substrate. A carrier wafer can be bonded to the active device to allow the active device to be inverted so that the passive device and associated contacts can be electrically coupled from a back side of the substrate.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a first substrate and a second substrate. The first substrate includes a first semiconductor layer, including a first trench isolation that extends through a portion of the first substrate layer; and a first interconnect structure, disposed over the first semiconductor layer. The second substrate includes a second semiconductor layer, including a plurality of semiconductor islands and surrounded by at least a second isolation penetrating the second semiconductor layer; a second interconnect structure, disposed over the second substrate layer and bonded to the first interconnect structure; and a dielectric layer, disposed over the second semiconductor layer opposite to the second interconnect structure. A method of manufacturing the semiconductor structure is also provided.

Abstract: Semiconductor structures and methods for manufacturing the same are provided. The semiconductor structure includes a plurality of nanostructures surrounded by a gate structure, and a source/drain (S/D) structure adjacent to the gate structure. The semiconductor structure includes a first S/D contact structure formed over a first side of the S/D structure, and a second S/D contact structure formed over a second side of the S/D structure. The second S/D contact structure includes a conductive layer. The semiconductor structure includes a dielectric layer adjacent to the second contact structure, and the dielectric layer is doped with germanium (Ge), and the dielectric layer is in direct contact with the conductive layer.

Abstract: The structure of a semiconductor device with different gate structures configured to provide ultra-low threshold voltages and a method of fabricating the semiconductor device are disclosed. The method includes forming first and second nanostructured channel regions in first and second nanostructured layers, respectively, and forming first and second gate-all-around (GAA) structures surrounding the first and second nanostructured channel regions, respectively. The forming the first and second GAA structures includes selectively forming an Al-based n-type work function metal layer and a Si-based capping layer on the first nanostructured channel regions, depositing a bi-layer of Al-free p-type work function metal layers on the first and second nanostructured channel regions, depositing a fluorine blocking layer on the bi-layer of Al-free p-type work function layers, and depositing a gate metal fill layer on the fluorine blocking layer.

Abstract: Embodiments include a FinFET transistor including an embedded resistor disposed in the fin between the source epitaxial region and the source contact. A control contact may be used to bias the embedded resistor, thereby changing the resistivity of the resistor. Edge gates of the FinFET transistor may be replaced with insulating structures. Multiple ones of the FinFET/embedded resistor combination may be utilized together in a common drain/common source contact design.

Abstract: A method is provided for forming a metal contact plug. In one step, a substrate, which is an Si substrate or an SiO2 substrate, is etched to form a contact hole. In one step, a dielectric liner layer is formed on a sidewall of the contact hole. In one step, the metal contact plug that is in contact with the dielectric liner layer is formed in the contact hole. In one step, an implantation process is performed on the substrate, so as to implant dopants having an atomic size greater than that of Si into the substrate.

Abstract: A complementary metal oxide semiconductor (CMOS) device includes a transistor of a first type formed over a first substrate, and a transistor of a second type formed over a second substrate. The CMOS device is formed when the transistor of the first type formed on the first substrate is bonded to the transistor of the second type formed over the second substrate.

Abstract: A semiconductor structure includes a plurality of semiconductor devices, each of which includes at least one channel layer, at least one interfacial layer, a gate dielectric layer, a gate electrode, and dipole elements. The at least one interfacial layer is disposed on the at least one channel layer. The gate dielectric layer is disposed over the at least one interfacial layer such that the at least one channel layer is separated from the gate dielectric layer through the at least one interfacial layer. The gate electrode is disposed on the gate dielectric layer. The dipole elements are present in the interfacial layer of at least one of the semiconductor devices in a predetermined amount such that the at least one of the semiconductor devices has a tunability of threshold voltage from that of the other of the semiconductor devices. Methods for manufacturing the semiconductor structure are also disclosed.

Abstract: A method for treating a semiconductor structure includes: forming the semiconductor structure which includes a carrier substrate, a device substrate, a semiconductor device formed on the device substrate, and a bonding layer formed to bond the semiconductor device with the carrier substrate, the device substrate having an upper surface which is faced upwardly, and which is opposite to the semiconductor device; and directing a chemical fluid to impinge the upper surface of the device substrate so as to remove an edge portion of the device substrate.

Abstract: A semiconductor device includes a multi-silicide structure comprising at least two conformal silicide layers. The multi-silicide structure may include a first conformal silicide layer on a source/drain, a second conformal silicide layer on the first conformal silicide layer, and a capping layer over the second conformal silicide layer. The semiconductor device includes a contact structure on the multi-silicide structure. The semiconductor device includes a dielectric material around the contact structure. In some implementations, a controller may determine etch process parameters to be used by an etch tool to perform an iteration of an atomic layer etch (ALE) process on the semiconductor device.

Abstract: A semiconductor structure includes a substrate including a first region and a second region, a first channel layer disposed in the first region and a second channel layer disposed in the second region, a first dielectric layer disposed on the first channel layer and a second dielectric layer disposed on the second channel layer, and a first gate electrode disposed on the first dielectric layer and a second gate electrode disposed on the second dielectric layer. The first channel layer in the first region includes Ge compound of a first Ge concentration, the second channel layer in the second region includes Ge compound of a second Ge concentration. The first Ge concentration in the first channel layer is greater than the second Ge concentration in the second channel layer.

Abstract: A semiconductor device includes a substrate, an interconnect, and a sensor. The substrate includes devices therein and has a front side and a rear side opposite to the front side. The interconnect is disposed on the front side and electrically coupled to the devices. The sensor is disposed over the substrate and in the interconnect, and includes a sensing element and a reference element. The sensing element is disposed in a topmost layer of the interconnect and exposed therefrom, where the sensing element is electrically coupled to a first device of the devices through the interconnect. The reference element is disposed in the topmost layer of the interconnect and exposed therefrom, where the reference element is laterally spaced from the sensing element and is electrically coupled to a second device of the devices through the interconnect.

Abstract: A semiconductor device includes a substrate, an interconnect, a second transistor, and a sensing film. The substrate includes devices disposed therein. The interconnect is disposed on the substrate and electrically coupled to the devices, where the interconnect includes a plurality of build-up layers and a through hole formed therein. The first transistor is disposed in the interconnect and vertically extends through at least one of the plurality of build-up layers, and the first transistor is electrically coupled to a first device of the devices through the interconnect. The second transistor is disposed in the interconnect and vertically extends through the at least one of the plurality of build-up layers, and the second transistor is electrically coupled to a second device of the devices through the interconnect, where the first transistor and the second transistor are laterally separated from one another through the through hole.

Abstract: A method is provided for forming a contact plug by bottom-up metal growth. In one step, a substrate is etched to form a contact hole that exposes a silicon-containing feature in the substrate. In one step, a silicide layer is formed on the silicon-containing feature. In one step, a metal seed layer is formed over the silicide layer. In one step, a metal contact layer is deposited over the metal seed layer to form the contact plug in the contact hole.

Abstract: In some embodiments, the present disclosure relates to an integrated chip that includes a first and second transistors arranged over a substrate. The first transistor includes first channel structures extending between first and second source/drain regions. A first gate electrode is arranged between the first channel structures, and a first protection layer is arranged over a topmost one of the first channel structures. The second transistor includes second channel structures extending between the second source/drain region and a third source/drain region. A second gate electrode is arranged between the second channel structures, and a second protection layer is arranged over a topmost one of the second channel structures. The integrated chip further includes a first interconnect structure arranged between the substrate and the first and second channel structures, and a contact plug structure coupled to the second source/drain region and arranged above the first and second gate electrodes.

Abstract: A method includes etching a dielectric layer to form a trench in the dielectric layer, depositing a metal layer extending into the trench, performing a nitridation process on the metal layer to convert a portion of the metal layer into a metal nitride layer, performing an oxidation process on the metal nitride layer to form a metal oxynitride layer, removing the metal oxynitride layer, and filling a metallic material into the trench using a bottom-up deposition process to form a contact plug.

Abstract: Some implementations described herein provide a semiconductor structure. The semiconductor structure may include a logic device disposed, at a first side of the logic device, on a carrier wafer of the semiconductor structure. The semiconductor structure may include a dielectric structure disposed on a second side of the logic device, the second side being opposite the first side. The semiconductor structure may include a memory device formed on the dielectric structure.