One illustrative method disclosed herein includes forming at least one first layer of insulating material above an upper surface of a top electrode of a memory cell, forming a patterned etch stop layer above the at least one first layer of insulating material, wherein the patterned etch stop layer has an opening that is positioned vertically above at least a portion of the upper surface of the top electrode and forming at least one second layer of insulating material above an upper surface of the etch stop layer. The method also includes forming a conductive contact opening that extends through the etch stop layer to expose at least a portion of the upper surface of the top electrode and forming a conductive contact structure in the conductive contact opening, wherein the conductive contact structure is conductively coupled to the upper surface of the top electrode.

A semiconductor device may be provided including a first series portion and a second series portion electrically connected in parallel with the first series portion. The first series portion may include a first MTJ stack and a first resistive element electrically connected in series. The second series portion may include a second MTJ stack and a second resistive element electrically connected in series. The first resistive element may include a third MTJ stack and the second resistive element may include a fourth MTJ stack. The first, second, third, and fourth MTJ stacks may include a same number of layers, which may include a fixed layer, a free layer, and a tunnelling barrier layer between the fixed layer and the free layer. Alternatively, the first resistive element may include a first transistor and the second resistive element may include a second transistor.

A memory device includes a bottom electrode, a tunneling junction disposed over the bottom electrode, and a top electrode disposed over the tunneling junction. The top electrode includes a first top electrode layer and a second top electrode layer above the first top electrode layer. The first and second top electrode layers include different material compositions. The first top electrode layer is thinner than the tunneling junction, and the second top electrode layer is thicker than the tunneling junction.

A method is provided. A substrate situated in a chamber is exposed to a halogen-containing gas comprising an element selected from the group consisting of silicon, germanium, carbon, titanium, and tin, and igniting a plasma to modify a surface of the substrate and form a modified surface. The substrate is exposed to an activated activation gas to etch at least part of the modified surface

A semiconductor device includes a substrate, a first magnetic tunnel junction (MTJ) structure, a second MTJ structure, and an interconnection structure. The first MTJ structure, the second MTJ structure, and the interconnection structure are disposed on the substrate. The interconnection structure is located between the first MTJ structure and the second MTJ structure in a first horizontal direction, and the interconnection structure includes a first metal interconnection and a second metal interconnection. The second metal interconnection is disposed on and contacts the first metal interconnection.

A method of forming a semiconductor memory device is disclosed. A top electrode layer is formed on the MTJ stack layer. A patterned buffer layer is formed to cover only the logic circuit region. A hard mask layer is formed on the top electrode layer and the patterned buffer layer. A patterned resist layer is formed on the hard mask layer. A first etching process is performed to etch the hard mask layer and the top electrode layer not covered by the patterned resist layer in the memory region and the hard mask layer, the patterned buffer layer and the top electrode layer in the logic circuit region, thereby forming a top electrode on the MTJ stack layer in the memory region and a remaining top electrode layer covering only the logic circuit region on the MTJ stack layer.

A topological material includes a lattice crystalline structure; and a material defect in the lattice crystalline structure that is treatable by hydrogen passivation that chemically mitigates an electronic charge associated with the material defect. The lattice crystalline structure includes dangling bonds in an atomic arrangement of the material defect of the lattice crystalline structure, and the hydrogen passivation may apply hydrogen to chemically passivate the dangling bonds of the material defect. The hydrogen passivation may be achieved by diffusing hydrogen into common materials of the lattice crystalline structure. The hydrogen passivation may chemically and/or electrostatically neutralize an electronic activity associated with the material defect.

A magnetic structure capable of field-free spin-orbit torque switching includes a spin-orbit coupling base layer and a ferromagnetic layer formed thereon. The spin-orbit coupling base layer is made from a particular crystal material. The ferromagnetic layer has magnetization perpendicular to a plane coupled to the spin-orbit coupling base layer, and is made from a particular ferromagnetic material with perpendicular magnetic anisotropy. The perpendicular magnetization of the ferromagnetic layer is switchable by an in plane current applied to the spin-orbit coupling base layer without application of an external magnetic field. A memory device and a production method regarding the magnetic structure are also provided.

An apparatus is provided which comprises: a magnetic junction having a magnet with perpendicular magnetic anisotropy (PMA) relative to an x-y plane of a device. In some embodiments, the apparatus comprises an interconnect partially adjacent to the structure of the magnetic junction, wherein the interconnect comprises a spin orbit material, wherein the interconnect has a pocket comprising non-spin orbit material, wherein the pocket is adjacent to the magnet of the magnetic junction. In some embodiments, the non-spin orbit material comprises metal which includes one or more of: Cu, Al, Ag, or Au.

An insertion layer for perpendicular spin orbit torque (SOT) memory devices between the SOT electrode and the free magnetic layer, memory devices and computing platforms employing such insertion layers, and methods for forming them are discussed. The insertion layer is predominantly tungsten and improves thermal stability and perpendicular magnetic anisotropy in the free magnetic layer.