Abstract: A semiconductor includes a first GAA FET and second GAA FET. The second GAA FET includes a first gate dielectric and second gate dielectric within its gate structure. The first GAA FET includes just the first gate dielectric within its gate structure. The gate dielectric structure of the first GAA FET provides for a nominal or a lesser effective gate dielectric or gate dielectric resistance relative to an effective gate dielectric structure of the second GAA FET. The first GAA FET further includes a first gate conductor within its gate structure and the second GAA FET further includes the first gate conductor and a second gate conductor within its gate structure. The first gate conductor and the second gate conductor are separated by the second gate dielectric.

Abstract: A semiconductor structure having a backside contact structure with increased contact area includes a plurality of source/drain regions within a field effect transistor, each of the plurality of source/drain regions includes a top portion having an inverted V-shaped area. A backside power rail is electrically connected to at least one source/drain region through a backside metal contact. The backside metal contact wraps around a top portion of the at least one source/drain region. A tip of the top portion of the plurality of source/drain regions points towards the backside power rail with the top portion of the at least one source/drain region being in electric contact with the backside metal contact. A first epitaxial layer is in contact with a top portion of at least another source/drain region adjacent to the at least one source/drain region for electrically isolating the at least another source/drain region from the backside power rail.

Abstract: A semiconductor structure is presented including a backside contact of a nanosheet transistor positioned on a silicon (Si) layer of a wafer and a dielectric liner disposed between the backside contact and the Si layer such that the dielectric liner is located below gate spacers of the nanosheet transistor. The backside contact is closer to a backside of the wafer than a frontside of the wafer. The dielectric liner is vertically aligned with the gate spacers and the dielectric liner is vertically aligned with inner spacers of a nanosheet stack of the nanosheet transistor.

Abstract: A CMOS apparatus includes a semiconductor substrate that has a frontside and a backside opposite the frontside; a source/drain structure, which is disposed at the frontside of the substrate and has a backside that is adjacent to the substrate and a frontside that is opposite the backside of the source/drain structure; a backside interconnect layer, which is disposed at the backside of the substrate; a backside contact, which penetrates the substrate and electrically connects the source/drain structure to the backside interconnect layer; and a sigma-profiled dielectric structure that insulates first and second sides of the backside contact from the substrate.

Abstract: A lower set of semiconductor channel layers, an upper set of semiconductor channel layers, a lower dielectric layer adjacent to the lower set of semiconductor channel layers, the lower dielectric layer includes a first polarity stress on the lower set of semiconductor channel layers, and an upper dielectric layer adjacent to the upper set of semiconductor channel layers, the lower dielectric layer includes a second polarity stress on the upper set of semiconductor channel layers with opposite polarity stress of the first polarity stress. Forming a lower stack of nanosheet layers and an upper stack of nanosheet layers, forming a lower dielectric layer adjacent to the lower stack of nanosheet layers, the lower dielectric layer includes a first polarity stress, and forming an upper dielectric layer adjacent to the upper stack of nanosheet layers, the upper dielectric layer includes a second polarity stress with opposite polarity.

Abstract: The present invention provides semiconductor structures. The semiconductor structures may include a peripheral complimentary metal-oxide semiconductor (CMOS) substrate, a first vertical NAND cell on a first side of the CMOS substrate, and a second vertical NAND cell on a second side of the CMOS substrate opposite the first side.

Abstract: An integrated circuit structure includes a memory cell and multiple transistors therein. The multiple transistors are formed using channels including a stack having alternating layers of conductive semiconductor material and layers of other material that are insulative. Two or more of the multiple transistors have a same number of layers of the conductive semiconductor material in corresponding channel regions but have different numbers of active layers and inactive layers of the conductive semiconductor material. An active layer is a layer forming a channel in the channel region that is electrically coupled to S/D regions in a corresponding transistor, while a floating layer is a layer in the channel region electrically isolated from the S/D regions in the corresponding transistor. Methods for forming the integrated circuit structure are disclosed.

Abstract: A semiconductor structure includes a first source/drain contact disposed between a first gate structure and a second gate structure, a dielectric cap disposed on the first source/drain contact, and a first gate contact disposed over the dielectric cap. The first gate contact connects the first gate structure with the second gate structure.

Abstract: A semiconductor device including a substrate having a dense array region and an isolation region. The semiconductor device includes plurality of first fin structures of stacked nanosheets is present in the dense array region separated by a single pitch, wherein each fin structure in the first plurality of fin structures has a same first nanosheet height as measured from an upper surface of the substrate in the dense array region. The semiconductor device further includes at least one second fin structure of stacked nanosheets is present in the isolation region, wherein a number of second fin structure in the isolation region is less than a number of first fin structures in the dense array region, the at least one fin structure having a second nano sheet height that is measured from the upper surface of the substrate in the isolation region that is the same as the first nanosheet height.

Abstract: Backside and frontside contact structures wrapping around source/drain regions provide increased contact areas for electrical connections and allow increased silicide areas. Sidewall metallization of epitaxially grown source/drain regions provides source/drain sidewall contacts that enable wrap-around contact formation on both the front side and the back side of a semiconductor device layer. Front side and back side contact metallization over the source/drain sidewall contacts allows wrap-around contact structures on both sides of the device layer.

Abstract: A semiconductor structure is presented including a first source/drain (S/D) epi region having a first contact completely wrapping around the first S/D epi region, the first contact electrically connected to a backside power delivery network (BSPDN) and a second S/D epi region having a second contact directly contacting a first sidewall, a second sidewall, and a top surface of the second S/D epi region, the second contact electrically connected to back-end-of-line (BEOL) components.

Abstract: Backside self-aligned contact designs using a replacement contact process with unique placeholder profile are provided. In one aspect, a semiconductor device includes: a field-effect transistor(s) on a frontside of the device; backside power rails on a backside of the device; a backside source/drain region contact connecting a given one of the backside power rails to a source/drain region of the field-effect transistor(s), and a dielectric placeholder(s) between the given backside power rail and another source/drain region of the field-effect transistor(s), where a first end of the dielectric placeholder(s) having a width W1 directly contacts the given backside power rail, a second end of the dielectric placeholder(s) having a width W2 directly contacts the other source/drain region, where W1>W2. The field-effect transistor(s) can include a stack of active layers with bottom dielectric isolation, and a gate-all-around configuration.

Abstract: Embodiments of present invention provide a ferroelectric random-access memory (FeRAM) cell. The FeRAM cell includes a vertical channel between a bottom source/drain region and a top source/drain region; a gate oxide surrounding the vertical channel; and a ferroelectric layer surrounding the gate oxide, wherein the ferroelectric layer has two or more sections of different horizontal thicknesses between the bottom source/drain region and the top source/drain region. A method of manufacturing the FeRAM cell is also provided.

Abstract: A long channel transistor structure including a first transistor array adjacent to a second transistor array, a third transistor array adjacent to a fourth transistor array, where the third transistor array and the fourth transistor array are arranged above the first transistor array and the second transistor array, and a continuous channel path through channels of the first transistor array, the second transistor array, the third transistor array, and the fourth transistor array.

Abstract: A semiconductor structure comprises one or more transistor devices on a first side of the semiconductor structure, one or more transistor devices on a second side of the semiconductor structure, the second side being opposite the first side, and a dielectric isolation layer separating the one or more transistor devices on the first side of the semiconductor structure from the one or more transistor devices on the second side of the semiconductor structure. The one or more transistor devices on the second side of the semiconductor structure comprise channel layers on one side of the dielectric isolation layer and source/drain regions that are independent of source/drain regions of the one or more transistor devices on the first side of the semiconductor structure.

Abstract: Embodiments of present invention provide a resistive random-access memory (RRAM) cell. The RRAM cell includes a bottom electrode; a metal oxide layer, the metal oxide layer having a central portion that is in direct contact with the bottom electrode, a peripheral portion that is nonplanar with the central portion, and a vertical portion between the central portion and the peripheral portion; and a top electrode directly above the metal oxide layer. A method of manufacturing the RRAM cell is also provided.

Abstract: A microelectronic structure comprises a first stacked device structure comprising a first upper device and a first lower device, a second stacked device structure comprising a second upper device and a second lower device, and an isolation pillar structure located between the first and second stacked device structures. The isolation pillar structure has an upper section contacting the first and second upper devices and a lower section contacting the first and second lower devices. The upper section of the isolation pillar structure has a first width and the lower section of the isolation pillar structure has a second width different than the first width.

Abstract: Embodiments of present invention provide a semiconductor structure. The semiconductor structure includes a first transistor, a second transistor, and a third transistor separated by their respective source/drain regions; and a diffusion break between the second transistor and the third transistor, wherein a first distance between a center of a gate of the first transistor and a center of a gate of the second transistor is more than half of a second distance between the center of the gate of the second transistor and a center of a gate of the third transistor. A method of manufacturing the semiconductor structure is also provided.

Abstract: Embodiments of the invention include a single stack dual channel gate-all-around nanosheet with strained PFET and bottom dielectric isolation NFET. A PFET comprising at least one silicon germanium channel is formed. An NFET comprising at least one silicon channel is formed, the PFET being positioned laterally to the NFET, the at least one silicon channel and the at least one silicon germanium channel being staggered in a vertical direction.

Abstract: A first source drain region adjacent to a first transistor, a second source drain region adjacent to a second transistor, an upper source drain contact above the first source drain region, a bottom source drain contact below the second source drain region, the bottom and the upper source drain contacts are on opposite sides, a horizontal surface of the bottom source drain contact is adjacent to a horizontal surface of dielectric side spacers surrounding the second source drain region. An embodiment where a bottom source drain contact surrounds vertical sides of a source drain region. A method including forming a forming a first and a second nanosheet stacks, forming a top source drain contact to a first source drain region adjacent to the first nanosheet stack, forming a bottom source drain contact to a lower horizontal surface of a second source drain region adjacent to the second nanosheet stack.