Abstract: A field effect device is provided. The field effect device includes a semiconductor nanosheet segment above a substrate, and a T-shaped inner spacer on the semiconductor nanosheet segment. The field effect device further includes a gate dielectric layer on the semiconductor nanosheet segment, and a first work function material plug on the gate dielectric layer. The field effect device further includes a second work function material layer on the first work function material plug and a center portion of the gate dielectric layer, wherein the second work function material layer is a different work function material from the first work function material plug.

Abstract: A method of manufacturing an MRAM device includes forming an MTJ stack on a substrate, forming a hardmask layer on the MTJ stack, forming etch pattern pads on the hardmask, forming a spacer on the sides of the etch pattern pads to form first openings exposing the hardmask, patterning the MTJ stack by a first etch using the first openings to form a plurality of first MTJ pillars separated by first vias, filling the first vias with a first dielectric, removing the spacers from the etch pattern pads to form a plurality of second openings between the first dielectric and the etch pattern pads, patterning the plurality of first MTJ pillars by a second etch using the second openings to form a plurality of second MTJ pillars separated by second vias and filling the second vias with a second dielectric to encapsulate the plurality of second MTJ pillars.

Abstract: A method is presented for selective dipole layer modulation. The method includes forming a nanosheet stack over a substrate, the nanosheet stack including alternating layers of a first semiconductor material, a second semiconductor material, and a third semiconductor material, etching the first and second semiconductor materials to define indentations, forming first inner spacers within the indentations, removing residual of the first semiconductor material, forming second inner spacers adjacent the first inner spacers, removing the remaining first and second semiconductor materials to define openings adjacent the first inner spacers, and filling the openings with a dipole layer stack to create multiple work function gate stacks with multiple threshold voltages (Vt) without metal gate patterning due to pinch-off exhibited between the first inner spacers and a nanosheet channel.

Abstract: A memory structure, i.e., magnetoresistive random access memory (MRAM) structure, is provided that includes a seeding area including at least a tunnel barrier seed layer located beneath a chemical templating layer that is wider than the magnetic tunnel junction (MTJ) structure that is located on the chemical templating layer. Redeposited metallic material is located on at least a sidewall of the tunnel barrier seed layer of the seeding area so as to shunt that area of the structure. The memory structure has reduced resistance with minimal tunnel magnetoresistance (TMR) loss penalty.

Abstract: A method for manufacturing a semiconductor device includes forming a plurality of fins on a substrate. The plurality of fins each include a first portion having a first width, and a second portion having a second width greater than the first width. The method also includes forming a sacrificial layer on the substrate in a space between a first fin and a second fin of the plurality of fins, wherein the first fin and the second fin correspond to a vertical transistor. In the method, lower portions of the first and second fins are removed, and an epitaxial region is formed under remaining portions of the first and second fins. The sacrificial layer is removed from the space between the first fin and the second fin after forming the epitaxial region.

Abstract: The embodiments herein describe a vertical field effect transistor (FET) with a gate that includes different work function metals (WFMs). Each WFM can be made up of one material (or one layer) or multiple materials forming multiple layers. In any case, the gate includes at least two different WFMs. For example, a first WFM may have a different material or layer than a second WFM in the gate, or one layer of the first WFM may have a different thickness than a corresponding layer in the second WFM. Having different WFMs in the gate can reduce the gate induced drain leakage (GIDL) in the FET.

Abstract: Embodiments of the invention are directed to a structure that includes a resistive switching device (RSD). The RSD includes a first terminal having an outer sidewall surface; a second terminal; an active region having a switchable conduction state; and a first protective layer on the outer sidewall surface of the first terminal.

Abstract: Embodiments of the invention are directed to a transistor device that includes a channel stack having stacked, spaced-apart, channel layers. A first source or drain (S/D) region is communicatively coupled to the channel stack. A tunnel extends through the channel stack, wherein the tunnel includes a central region and a first set of end regions. The first set of end regions is positioned closer to the first S/D region than the central region is to the first S/D region. A first type of work-function metal (WFM) is formed in the first set of end regions, the first WFM having a first work-function (WF). A second type of WFM is formed in the central region, the second type of WFM having a second WF, wherein the first WF is different than the second WF.

Abstract: A spin-orbit torque magnetoresistive random-access memory device formed by forming an array of transistors, where a column of the array includes a source line contacting the source contact of each transistor of the column, forming a spin-orbit-torque (SOT) line contacting the drain contacts of the transistors of the row, and forming an array of unit cells, each unit cell including a spin-orbit-torque (SOT) magnetoresistive random access memory (MRAM) cell stack disposed above and in electrical contact with the SOT line, where the SOT-MRAM cell stack includes a free layer, a tunnel junction layer, and a reference layer, a diode structure above and in electrical contact with the SOT-MRAM cell stack, an upper electrode disposed above and in electrical contact with the diode structure.

Abstract: A spin-orbit torque magnetoresistive random-access memory device formed by fabricating a spin-Hall-effect (SHE) layer above and in electrical contact with a transistor, forming a spin-orbit-torque (SOT) magnetoresistive random access memory (MRAM) cell stack disposed above and in electrical contact with the SHE rail, wherein the SOT-MRAM cell stack comprises a free layer, a tunnel junction layer, and a reference layer, forming a cylindrical diode structure above and in electrical contact with the SOT-MRAM cell stack, forming a write line disposed in electrical contact with the SHE rail, and forming a read line disposed above and adjacent to an outer cylindrical electrode of the diode structure.

Abstract: An approach to provide a structure of a double magnetic tunnel junction device with two spacers that includes a bottom magnetic tunnel junction stack, a spin conducting layer on the bottom magnetic tunnel junction stack, a top magnetic tunnel junction stack on the spin conduction layer, a first dielectric spacer on sides of the top magnetic tunnel junction stack and a portion of a top surface of the spin conduction layer, and a second dielectric spacer on the first spacer. The double magnetic tunnel device includes the top magnetic tunnel junction stack with a width that is less than the width of the bottom magnetic tunnel junction stack.

Abstract: A method of manufacturing a magnetic tunnel junction device is provided. The method includes forming an MTJ stack including a reference layer, a tunnel barrier layer formed on the reference layer, a free layer formed on the barrier layer, and a cap layer formed on the free layer. The method also includes performing ion beam etching (IBE) through each layer of the MTJ stack to form at least one MTJ pillar. The method also includes forming an isolation layer on sidewalls of at least the tunnel barrier layer, the isolation layer comprising a same material as that of the tunnel barrier layer. A combined width of the isolation layer and the tunnel barrier layer is equal to or greater than a width of at least one of the reference layer and the free layer.

Abstract: A semiconductor device including at least one nanosheet and epitaxial source and drain regions are present on opposing ends of the at least one nanosheet. A gate structure is present on a channel of the at least one nanosheet. The gate structure includes a first work function metal gate portion present at a junction portion of the source and drain regions that interfaces with the channel portion of the at least one nanosheet, and a second work function metal gate portion present on a central portion of the channel of the at least one nanosheet. The amount of metal containing nitride in the second work function metal gate portion is greater than an amount of metal containing nitride in the first work function metal gate portion. The device further includes a rotated T-shaped dielectric spacer present between the gate structure and the epitaxial source and drain regions.

Abstract: A method of manufacturing and resultant device are directed to an inverted wide-base double magnetic tunnel junction device having both high-efficiency and high-retention arrays. The method includes a method of manufacturing, on a common stack, a high-efficiency array and a high-retention array for an inverted wide-base double magnetic tunnel junction device. The method comprises, for the high-efficiency array and the high-retention array, forming a first magnetic tunnel junction stack (MTJ2), forming a spin conducting layer on the MTJ2, and forming a second magnetic tunnel junction stack (MTJ1) on the spin conducting layer. The first magnetic tunnel junction stack for the high-retention array has a high-retention critical dimension (CD) (HRCD) that is larger than a high-efficiency CD (HECD) of the first magnetic tunnel junction stack for the high-efficiency array. The second magnetic tunnel junction stack (MTJ1) is shorted for the high-retention array and is not shorted for the high-efficiency array.

Abstract: A semiconductor device including a second magnetic tunnel junction stack aligned above a spin conductor layer above a first magnetic junction stack, a sidewall dielectric surrounding the second magnetic tunnel junction stack, a vertical side surface of the sidewall dielectric is aligned with vertical side surfaces of the spin conductor layer and the first magnetic junction stack. A method including forming a first magnetic tunnel junction stack, a spin conductor layer and a second magnetic tunnel junction stack, patterning the second magnetic tunnel junction stack, while not patterning the spin conductor layer and the first magnetic tunnel junction stack, forming a sidewall dielectric and a polymer layer on the sidewall dielectric. A method including patterning a second magnetic tunnel junction stack, while not patterning a spin conductor layer below the second magnetic tunnel junction stack nor a first magnetic tunnel junction stack below the spin conductor layer.

Abstract: A method for fabricating stacked resistive memory with individual switch control is provided. The method includes forming a first random access memory (ReRAM) device. The method further includes forming a second ReRAM device in a stacked nanosheet configuration on the first ReRAM device. The method also includes forming separate gate contacts for the first ReRAM device and the second ReRAM device.

Abstract: A semiconductor device including a magnetic tunnel junction stack, a metallic hard mask aligned above the magnetic tunnel junction stack and an air gap surrounding the metallic hard mask. A method including forming a magnetic tunnel junction stack, forming a metallic hard mask aligned above the magnetic tunnel junction stack, conformally forming a dielectric over the metallic hard mask and the magnetic tunnel junction stack, forming barrier on vertical side surfaces of the dielectric, and removing the dielectric between the metallic hard mask and the barrier. A method including forming a magnetic tunnel junction stack, forming a metallic hard mask aligned above the magnetic tunnel junction stack, conformally forming a dielectric over the metallic hard mask and the magnetic tunnel junction stack, selectively removing a portion of the dielectric surrounding the metallic hard mark.

Abstract: A tilted nanowire structure is provided which has an increased gate length as compared with a horizontally oriented semiconductor nanowire at the same pitch. Such a structure avoids complexity required for vertical transistors and can be fabricated on a bulk semiconductor substrate without significantly changing/modifying standard transistor fabrication processing.

Abstract: A method of forming a complementary metal oxide semiconductor (CMOS) device is provided. The method includes forming a separate gate structure on each of a pair of vertical fins, wherein the gate structures include a gate dielectric layer and a gate metal layer, and forming a protective liner layer on the gate structures. The method further includes heat treating the pair of gate structures, and replacing the protective liner layer with an encapsulation layer. The method further includes exposing a portion of the gate dielectric layer by recessing the encapsulation layer. The method further includes forming a top source/drain on the top surface of one of the pair of vertical fins, and subjecting the exposed portion of the gate dielectric layer to a second heat treatment conducted in an oxidizing atmosphere.

Abstract: Semiconductor devices and methods of forming the same include forming first recesses in a first stack of alternating sacrificial layers and channel layers. A first inner spacer sub-layer is formed in the first recesses from a first dielectric material. A second inner spacer sub-layer is formed in the first recesses from a second dielectric material, different from the first dielectric material. The sacrificial layers and the first inner spacer sub-layer are replaced with a gate stack in contact with the second inner spacer sub-layer.