One illustrative MRAM cell disclosed herein includes a bottom electrode, a top electrode positioned above the bottom electrode and an MTJ (Magnetic Tunnel Junction) element positioned above the bottom electrode and below the top electrode. In this example, the MTJ element includes a bottom insulation layer positioned above the bottom electrode, a top insulation layer positioned above the bottom electrode; and a first ferromagnetic material layer positioned between the bottom insulation layer and the top insulation layer.

Some embodiments relate to a memory device. The memory device includes a magnetoresistive random-access memory (MRAM) cell comprising a magnetic tunnel junction (MTJ). The MTJ device comprises a stack of layers, comprising a bottom electrode disposed over a substrate. A seed layer disposed over the bottom electrode. A buffer layer is disposed between the bottom electrode and the seed layer. The buffer layer prevents diffusion of a diffusive species from the bottom electrode to the seed layer.

Some embodiments relate to a memory device. The memory device includes a magnetoresistive random-access memory (MRAM) cell comprising a magnetic tunnel junction (MTJ). The MTJ device comprises a stack of layers, comprising a bottom electrode disposed over a substrate. A seed layer disposed over the bottom electrode. A buffer layer is disposed between the bottom electrode and the seed layer. The buffer layer prevents diffusion of a diffusive species from the bottom electrode to the seed layer.

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 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 first electrode including a spin-orbit material, a magnetic junction on a portion of the first electrode and a first structure including a dielectric on a portion of the first electrode. The first structure has a first sidewall and a second sidewall opposite to the first sidewall. The memory device further includes a second structure on a portion of the first electrode, where the second structure has a sidewall adjacent to the second sidewall of the first structure. The memory device further includes a first conductive interconnect above and coupled with each of the magnetic junction and the second structure and a second conductive interconnect below and coupled with the first electrode, where the second conductive interconnect is laterally distant from the magnetic junction and the second structure.

A semiconductor device includes a base structure of an embedded memory device including a bottom electrode contact (BEC) landing pad within a memory area of the embedded memory device and a first metallization level having at least a first conductive line within a logic area of the embedded memory device, a cap layer disposed on the base structure, a BEC disposed through the cap layer on the BEC landing pad, a memory pillar disposed on the BEC and the cap layer, encapsulation layers encapsulating the memory pillar to protect the memory stack, and a second metallization level including a second conductive line surrounding the top electrode, a via disposed on the first conductive line such that the second via is below the top electrode, and a third conductive line disposed on the via to enable the memory pillar to be fitted between the first and second metallization levels.

A semiconductor device includes a base structure of an embedded memory device including a bottom electrode contact (BEC) landing pad within a memory area of the embedded memory device and a first metallization level having at least a first conductive line within a logic area of the embedded memory device, a cap layer disposed on the base structure, a BEC disposed through the cap layer on the BEC landing pad, a memory pillar disposed on the BEC and the cap layer, encapsulation layers encapsulating the memory pillar to protect the memory stack, and a second metallization level including a second conductive line surrounding the top electrode, a via disposed on the first conductive line such that the second via is below the top electrode, and a third conductive line disposed on the via to enable the memory pillar to be fitted between the first and second metallization levels.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a magnetic tunnel junction arranged between a bottom electrode and a top electrode and surrounded by a dielectric structure disposed over a substrate. The top electrode has a width that decreases as a height of the top electrode increases. A bottom electrode via couples the bottom electrode to a lower interconnect. An upper interconnect structure is coupled to the top electrode. The upper interconnect structure has a vertically extending surface that is disposed laterally between first and second outermost sidewalls of the upper interconnect structure and along a sidewall of the top electrode. The vertically extending surface and the first outermost sidewall are connected to a bottom surface of the upper interconnect structure that is vertically below a top of the top electrode.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a magnetic tunnel junction arranged between a bottom electrode and a top electrode and surrounded by a dielectric structure disposed over a substrate. The top electrode has a width that decreases as a height of the top electrode increases. A bottom electrode via couples the bottom electrode to a lower interconnect. An upper interconnect structure is coupled to the top electrode. The upper interconnect structure has a vertically extending surface that is disposed laterally between first and second outermost sidewalls of the upper interconnect structure and along a sidewall of the top electrode. The vertically extending surface and the first outermost sidewall are connected to a bottom surface of the upper interconnect structure that is vertically below a top of the top electrode.