Abstract: Embodiments of present invention provide a magnetoresistive random-access-memory (MRAM). The MRAM includes a reference layer; a tunnel barrier layer of magnesium-oxide (MgO); and a free layer, where the free layer includes a first cobalt-iron-boron (CoFeB) layer on top of the tunnel barrier layer; a spacer layer on top of the first CoFeB layer; a second CoFeB layer on top of the spacer layer; and a capping layer of MgO on top of the second CoFeB layer. Additionally, the first and the second CoFeB layer are substantially depleted of boron (B) to include respectively a first region adjacent to the tunnel barrier layer and the capping layer respectively and a second region adjacent to the spacer layer, where the first regions of the first and the second CoFeB layer include crystallized cobalt-iron (CoFe) and the second regions of the first and the second CoFeB layer include amorphous CoFe alloy.

Abstract: A magnetic tunnel junction (MTJ) stack structure includes a reference layer; a tunnel barrier; and a free layer that comprises three distinct materials. All of the three distinct materials in the free layer are magnetic material. One of the three distinct materials in the free layer is a C38 structure alloy.

Abstract: A method of forming a contact to a semiconductor device is provided that forms an alloy composed of nickel (Ni), platinum (Pt), aluminum (Al), titanium (Ti) and a semiconductor material. The methods may include forming a nickel and platinum semiconductor alloy at a base of a via. A titanium layer having an angstrom scale thickness is deposited in the via in contact with the nickel platinum semiconductor alloy. An aluminum containing fill is deposited atop the titanium layer. A forming gas anneal including an oxygen containing atmosphere is applied to the structure to provide a contact alloy comprising nickel, platinum, aluminum, titanium and a semiconductor element from the contact surface of the semiconductor device.

Abstract: Devices, systems, methods, and/or computer-implemented methods that can facilitate protection of a substrate in a qubit device using sacrificial material are provided. According to an embodiment, a device can comprise a superconducting lead provided on a pillar of a sacrificial material provided on a substrate. The device can further comprise a collapsed superconducting junction provided on the substrate and coupled to the superconducting lead.

Abstract: Magnetic tunnel junction pillars including ordered alloy, bottom free layers are formed using simplified seed structures including textured magnesium oxide. The seed structures can have relatively small thicknesses, thereby reducing roughness of layers formed above the seed structures and facilitating magnetic tunnel junction pillar formation from multi-layer films including such seed structures.

Abstract: A method of forming a contact to a semiconductor device is provided that forms an alloy composed of nickel (Ni), platinum (Pt), aluminum (Al), titanium (Ti) and a semiconductor material. The methods may include forming a nickel and platinum semiconductor alloy at a base of a via. A titanium layer having an angstrom scale thickness is deposited in the via in contact with the nickel platinum semiconductor alloy. An aluminum containing fill is deposited atop the titanium layer. A forming gas anneal including an oxygen containing atmosphere is applied to the structure to provide a contact alloy comprising nickel, platinum, aluminum, titanium and a semiconductor element from the contact surface of the semiconductor device.

Abstract: Systems and techniques that facilitate spurious junction prevention via in-situ ion milling are provided. In various embodiments, a method can comprise forming a tunnel barrier of a Josephson junction on a substrate during a shadow evaporation process. In various instances, the method can further comprise etching an exposed portion of the tunnel barrier during the shadow evaporation process. In various embodiments, the shadow evaporation process can comprise patterning a resist stack onto the substrate. In various instances, the etching the exposed portion of the tunnel barrier can leave a protected portion of the tunnel barrier within a shadow of the resist stack. In various instances, the shadow of the resist stack can be based on a direction of the etching the exposed portion of the tunnel barrier.

Abstract: Systems and techniques that facilitate spurious junction prevention via in-situ ion milling are provided. In various embodiments, a method can comprise forming a tunnel barrier of a Josephson junction on a substrate during a shadow evaporation process. In various instances, the method can further comprise etching an exposed portion of the tunnel barrier during the shadow evaporation process. In various embodiments, the shadow evaporation process can comprise patterning a resist stack onto the substrate. In various instances, the etching the exposed portion of the tunnel barrier can leave a protected portion of the tunnel barrier within a shadow of the resist stack. In various instances, the shadow of the resist stack can be based on a direction of the etching the exposed portion of the tunnel barrier.

Abstract: A superconducting circuit includes a Josephson junction device including a lower superconducting material layer formed on a substrate and a junction layer formed on the lower superconducting material layer. The superconducting circuit also includes an upper superconducting material layer formed over the junction layer. At least the lower superconducting material layer comprises grains having a size that is larger than a size of the Josephson junction.

Abstract: Devices, systems, methods, and/or computer-implemented methods that can facilitate protection of a substrate in a qubit device using sacrificial material are provided. According to an embodiment, a device can comprise a superconducting lead provided on a pillar of a sacrificial material provided on a substrate. The device can further comprise a collapsed superconducting junction provided on the substrate and coupled to the superconducting lead.

Abstract: A superconducting circuit includes a Josephson junction device including a lower superconducting material layer formed on a substrate and a junction layer formed on the lower superconducting material layer. The superconducting circuit also includes an upper superconducting material layer formed over the junction layer. At least the lower superconducting material layer comprises grains having a size that is larger than a size of the Josephson junction.

Abstract: Systems and techniques that facilitate spurious junction prevention via in-situ ion milling are provided. In various embodiments, a method can comprise forming a tunnel barrier of a Josephson junction on a substrate during a shadow evaporation process. In various instances, the method can further comprise etching an exposed portion of the tunnel barrier during the shadow evaporation process. In various embodiments, the shadow evaporation process can comprise patterning a resist stack onto the substrate. In various instances, the etching the exposed portion of the tunnel barrier can leave a protected portion of the tunnel barrier within a shadow of the resist stack. In various instances, the shadow of the resist stack can be based on a direction of the etching the exposed portion of the tunnel barrier.

Abstract: A method of forming a contact to a semiconductor device is provided that forms an alloy composed of nickel (Ni), platinum (Pt), aluminum (Al), titanium (Ti) and a semiconductor material. The methods may include forming a nickel and platinum semiconductor alloy at a base of a via. A titanium layer having an angstrom scale thickness is deposited in the via in contact with the nickel platinum semiconductor alloy. An aluminum containing fill is deposited atop the titanium layer. A forming gas anneal including an oxygen containing atmosphere is applied to the structure to provide a contact alloy comprising nickel, platinum, aluminum, titanium and a semiconductor element from the contact surface of the semiconductor device.

Abstract: A method of forming a semiconductor device that includes forming a metal oxide material on a III-V semiconductor channel region or a germanium containing channel region; and treating the metal oxide material with an oxidation process. The method may further include depositing of a hafnium containing oxide on the metal oxide material after the oxidation process, and forming a gate conductor atop the hafnium containing oxide. The source and drain regions are on present on opposing sides of the gate structure including the metal oxide material, the hafnium containing oxide and the gate conductor.

Abstract: A method of forming a contact to a semiconductor device is provided that forms an alloy composed of nickel (Ni), platinum (Pt), aluminum (Al), titanium (Ti) and a semiconductor material. The methods may include forming a nickel and platinum semiconductor alloy at a base of a via. A titanium layer having an angstrom scale thickness is deposited in the via in contact with the nickel platinum semiconductor alloy. An aluminum containing fill is deposited atop the titanium layer. A forming gas anneal including an oxygen containing atmosphere is applied to the structure to provide a contact alloy comprising nickel, platinum, aluminum, titanium and a semiconductor element from the contact surface of the semiconductor device.

Abstract: A method of forming a contact to a semiconductor device is provided that forms an alloy composed of nickel (Ni), platinum (Pt), aluminum (Al), titanium (Ti) and a semiconductor material. The methods may include forming a nickel and platinum semiconductor alloy at a base of a via. A titanium layer having an angstrom scale thickness is deposited in the via in contact with the nickel platinum semiconductor alloy. An aluminum containing fill is deposited atop the titanium layer. A forming gas anneal including an oxygen containing atmosphere is applied to the structure to provide a contact alloy comprising nickel, platinum, aluminum, titanium and a semiconductor element from the contact surface of the semiconductor device.

Abstract: A method of forming a contact to a semiconductor device is provided that forms an alloy composed of nickel (Ni), platinum (Pt), aluminum (Al), titanium (Ti) and a semiconductor material. The methods may include forming a nickel and platinum semiconductor alloy at a base of a via. A titanium layer having an angstrom scale thickness is deposited in the via in contact with the nickel platinum semiconductor alloy. An aluminum containing fill is deposited atop the titanium layer. A forming gas anneal including an oxygen containing atmosphere is applied to the structure to provide a contact alloy comprising nickel, platinum, aluminum, titanium and a semiconductor element from the contact surface of the semiconductor device.

Abstract: Embodiments are directed to a method of forming a semiconductor device and resulting structures having a shallow, abrupt and highly activated tin (Sn) extension implant junction. The method includes forming a semiconductor fin on a substrate. A gate is formed over a channel region of the semiconductor fin. A Sn extension implant junction is formed on a surface of the semiconductor fin in the channel region.

Abstract: CMOS-compatible non-filamentary RRAM devices and techniques for formation thereof are provided. In one aspect, a method of forming a non-filamentary RRAM device includes: depositing a base oxide layer (e.g., hafnium oxide) on a bottom electrode; depositing a cap layer (e.g., amorphous silicon) on the base oxide layer; and depositing a top electrode on the cap layer, wherein the cap layer and the top electrode are deposited in-situ without any air exposure in between such that there is an absence of oxide at an interface between the cap layer and the top electrode. A low resistivity layer can optionally be deposited on the top electrode. An RRAM device and a computing device having a crossbar array of the present RRAM cells are also provided.

Abstract: CMOS-compatible non-filamentary RRAM devices and techniques for formation thereof are provided. In one aspect, a method of forming a non-filamentary RRAM device includes: depositing a base oxide layer (e.g., hafnium oxide) on a bottom electrode; depositing a cap layer (e.g., amorphous silicon) on the base oxide layer; and depositing a top electrode on the cap layer, wherein the cap layer and the top electrode are deposited in-situ without any air exposure in between such that there is an absence of oxide at an interface between the cap layer and the top electrode. A low resistivity layer can optionally be deposited on the top electrode. An RRAM device and a computing device having a crossbar array of the present RRAM cells are also provided.