A memory device including bit lines, auxiliary lines, selectors, and memory cells is provided. The word lines are intersected with the bit lines. The auxiliary lines are disposed between the word lines and the of bit lines. The selectors are inserted between the bit lines and the auxiliary lines. The memory cells are inserted between the word lines and the auxiliary lines.

Each memory cell in an array includes a vertical stack that comprises a bottom electrode, a memory element, and a top electrode. An etch stop dielectric layer is formed over the array of memory cells. A first dielectric matrix layer is formed over the etch stop dielectric layer. The top surface of the first dielectric matrix layer is raised in a memory array region relative to a logic region due to topography. The first dielectric matrix layer is planarized by performing a chemical mechanical planarization process using top portions of the etch stop dielectric layer. A second dielectric matrix layer is formed over the first dielectric matrix layer. Metallic cell contact structures are formed through the second dielectric matrix layer on a respective subset of the top electrodes over vertically protruding portions of the etch stop dielectric layer that laterally surround the array of vertical stacks.

The present invention is directed to a magnetic memory cell including a magnetic tunnel junction (MTJ) memory element and a two-terminal bidirectional selector coupled in series between two conductive lines. The MTJ memory element includes a magnetic free layer, a magnetic reference layer, and an insulating tunnel junction layer interposed therebetween. The two-terminal bidirectional selector includes bottom and top electrodes, first and third volatile switching layers interposed between the bottom and top electrodes, and a second volatile switching layer interposed between the first and third volatile switching layers. The bottom and top electrodes each independently include one of titanium nitride or iridium. The first and third volatile switching layers each include tantalum oxide and silver. The second volatile switching layer includes hafnium oxide and has a higher electrical resistance than the first and third volatile switching layers.

A semiconductor device includes a magnetic random access memory (MRAM) cell. The MRAM cell includes a first magnetic layer disposed over a substrate, a first non-magnetic material layer made of a non-magnetic material and disposed over the first magnetic layer, a second magnetic layer disposed over the first non-magnetic material layer, and a second non-magnetic material layer disposed over the second magnetic layer. The second magnetic layer includes a plurality of magnetic material pieces separated from each other.

A magnetoresistive device includes a magnetically fixed region and a magnetically free region positioned on opposite sides of a tunnel barrier region. One or more transition regions, including at least a first transition region and second transition region, is positioned between the magnetically fixed region and the tunnel barrier region. The first transition region includes a non-ferromagnetic transition metal and the second transition region includes an alloy including iron and boron.

Some embodiments relate to a method for manufacturing a memory device. The method includes forming a first masking layer disposed over a dielectric layer, the first masking layer exhibiting sidewalls defining an opening disposed above a magnetoresistive random-access memory (MRAM) cell located in an embedded memory region. A first etch is performed to form a first via opening within the dielectric layer above the MRAM cell. A top electrode via layer formed over the MRAM cell and the dielectric layer. A first planarization process performed on the top electrode via layer to remove part of the top electrode via layer and define a top electrode via having a substantially flat top surface.

A weight cell, an electronic device and a device are provided. The weight cell includes a first resistive memory element and a second resistive memory element, a select transistor, and a layer of Spin Hall (SH) material disposed between the first resistive memory element and the second resistive memory element, the layer of the SH material including a first contact and a second contact. The first contact of the SH material is connected to a drain of the select transistor and the second contact of the SH material is connected to an external word line.

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.

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 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.