A semiconductor structure and a method for forming the semiconductor structure are provided. The semiconductor structure includes a substrate, and a conductive layer in the substrate and having a surface exposed by the substrate. A groove is formed in the substrate and adjacent to the conductive layer, and a sidewall of the groove exposes a portion of a sidewall surface of the conductive layer. The semiconductor structure also includes a lower electrode layer located in the groove and on a top surface of the conductive layer. The lower electrode layer covers the top surface and the portion of the sidewall surface of the conductive layer.

Semiconductor structure and methods of forming the same are provided. An exemplary method includes receiving a workpiece including a magnetic tunneling junction (MTJ) and a conductive capping layer disposed on the MTJ, depositing a first dielectric layer over the workpiece, performing a first planarization process to the first dielectric layer, and after the performing of the first planarization process, patterning the first dielectric layer to form an opening exposing a top surface of the conductive capping layer, selectively removing the conductive capping layer. The method also includes depositing an electrode layer to fill the opening and performing a second planarization process to the workpiece such that a top surface of the electrode layer and a top surface of the first dielectric layer are coplanar.

Damascene-based approaches for embedding spin hall MTJ devices into a logic processor, and the resulting structures, are described. In an example, a logic processor includes a logic region including a metallization layer. The logic processor also includes a memory array including a plurality of two-transistor one magnetic tunnel junction (MTJ) spin hall effect electrode (2T-1MTJ SHE electrode) bit cells. The spin hall effect electrodes of the 2T-1MTJ SHE electrode bit cells are disposed in a lower dielectric layer laterally adjacent to the metallization layer of the logic region. The MTJs of the 2T-1MTJ SHE electrode bit cells are disposed in an upper dielectric layer laterally adjacent to the metallization layer of the logic region.

A magnetic domain wall movement type magnetic recording element includes: a first ferromagnetic layer which includes a ferromagnetic body; a non-magnetic layer which faces the first ferromagnetic layer; and a magnetic recording layer which faces a surface of the non-magnetic layer on a side opposite to the first ferromagnetic layer and extends in a first direction. The magnetic recording layer has a concave-convex structure on a second surface opposite to a first surface which faces the non-magnetic layer.

The present disclosure relates to an integrated chip. The integrated chip includes a memory device surrounded by a dielectric structure disposed over a substrate. The memory device includes a data storage structure disposed between a bottom electrode and a top electrode. A top electrode via couples the top electrode to an upper interconnect wire. A first line is tangent to a first outermost sidewall of the top electrode via and a second line is tangent to an opposing second outermost sidewall of the top electrode via. The first line is oriented at a first angle with respect to a horizontal plane that is parallel to an upper surface of the substrate and the second line is oriented at a second angle with respect to the horizontal plane. The second angle is less than the first angle.

A method for fabricating semiconductor device includes the steps of: forming a first inter-metal dielectric (IMD) layer on a substrate; forming a metal interconnection in the first IMD layer; forming a bottom electrode layer and a pinned layer on the first IMD layer; forming a sacrificial layer on the pinned layer; patterning the sacrificial layer, the pinned layer, and the bottom electrode layer to form a first magnetic tunneling junction (MTJ); forming a second IMD layer around the first MTJ; and removing the sacrificial layer.

A method includes depositing a plurality of layers, which includes depositing a spin orbit coupling layer, depositing a dielectric layer over the spin orbit coupling layer, depositing a free layer over the dielectric layer, depositing a tunnel barrier layer over the free layer, and depositing a reference layer over the tunnel barrier layer. The method further includes performing a first patterning process to pattern the plurality of layers, and performing a second patterning process to pattern the reference layer, the tunnel barrier layer, the free layer, and the dielectric layer. The second patterning process stops on a top surface of the spin orbit coupling layer.

Various embodiments of the present disclosure are directed towards a memory device including a free layer overlying a reference layer. A tunnel barrier layer overlies the reference layer disposed over a semiconductor substrate. The free layer overlies the tunnel barrier layer, and a capping layer overlies the free layer. A shunting structure includes a conductive material that vertically extends continuously from an outer sidewall of the free layer to an outer sidewall of the capping layer.

In some embodiments, the present disclosure relates to a memory device that includes a spin orbit torque (SOT) layer arranged over a substrate. A magnetic tunnel junction (MTJ) structure may be arranged over the SOT layer. The MTJ structure includes a free layer, a reference layer, and a diffusion barrier layer disposed between the free layer and the reference layer. A first conductive wire is arranged below the SOT layer and coupled to the SOT layer. A second conductive wire is arranged below the SOT layer and coupled to the SOT layer. A third conductive wire is arranged over the MTJ structure. The memory device further includes a first selector structure arranged between the first conductive wire and the SOT layer.

Example implementations are concerned with magnetoresistive sensors and with corresponding fabrication methods for magnetoresistive sensors. One example here relates to a magnetoresistive sensor having a layer stack. The layer stack comprises a reference layer having a reference magnetization, which is fixed and has a first magnetic orientation. The layer stack comprises a magnetically free layer. The magnetically free layer has a magnetically free magnetization. The magnetically free magnetization is variable in the presence of an external magnetic field. The magnetically free magnetization has a second magnetic orientation in a ground state. One of the first or the second magnetic orientation is oriented in-plane and the other is oriented out-of-plane. The layer stack comprises a metal multilayer. In this case, either the metal multilayer is arranged adjacent to the magnetically free layer, or the metal multilayer constitutes the magnetically free layer.