A magnetic junction memory device is provided. The magnetic junction memory device including a sensing circuit including a sensing node, the sensing node being connected to a first end of a transistor and configured to change a voltage of the sensing node in accordance with a resistance of a magnetic junction memory cell, a gating voltage generator circuit configured to generate a gating voltage of the transistor using a reference resistor and a reference voltage, and a read circuit configured to read data from the magnetic junction memory cell using the reference voltage and the voltage of the sensing node.

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 including a semiconductor substrate and an interconnect structure is provided. The semiconductor substrate includes a transistor, wherein the transistor has a source region and a drain region. The interconnect structure is disposed over the semiconductor substrate, wherein the interconnect structure includes a plurality of interlayer dielectric layers, a first via and a memory cell. The plurality of interlayer dielectric layers are over the semiconductor substrate. The first via is embedded in at least two interlayer dielectric layers among the plurality of interlayer dielectric layers and electrically connected with the drain region of the transistor. The memory cell is disposed over the at least two interlayer dielectric layers among the plurality of interlayer dielectric layers and electrically connected with the first via.

A magnetic junction memory device is provided. The magnetic junction memory device including a sensing circuit including a sensing node, the sensing node being connected to a first end of a transistor and configured to change a voltage of the sensing node in accordance with a resistance of a magnetic junction memory cell, a gating voltage generator circuit configured to generate a gating voltage of the transistor using a reference resistor and a reference voltage, and a read circuit configured to read data from the magnetic junction memory cell using the reference voltage and the voltage of the sensing node.

In a method of manufacturing a semiconductor device, a first interlayer dielectric (ILD) layer is formed over a substrate, a CMP stop layer is formed over the first ILD layer, a trench opening is formed by patterning the CMP stop layer and the first ILD layer, an underlying first process mark is formed by forming a first conductive layer in the trench opening, a lower dielectric layer is formed over the underlying first process mark, a middle dielectric layer is formed over the lower dielectric layer, an upper dielectric layer is formed over the middle dielectric layer, a planarization operation is performed on the upper, middle and lower dielectric layers so that a part of the middle dielectric layer remains over the underlying first process mark, and a second process mark by the lower dielectric layer is formed by removing the remaining part of the middle dielectric layer.

Disclosed are examples of multiple bit magnetoresistive random access memory (MRAM) cells. A multiple bit MRAM cell may comprise a fixed layer, alternately stacked N tunnel barriers and N free layers, and a tunnel cap. N, which may represent number of bits of the MRAM cell, may be greater than or equal to two. Magnetic moment of the fixed layer may be fixed in one perpendicular direction. Magnetic moments of the free layers may be switchable from one to other perpendicular directions upon application of switch currents. The switch currents may be different for different layers. The magnetic moments of the free layers may be switched separately or otherwise independently of other free layers when the switch currents are applied separately.

A semiconductor device includes a plurality of magnetic tunnel junction (MTJ) structures in an interlayer insulating layer on a substrate. A blocking layer is on the interlayer insulating layer and the plurality of MTJ structures. An upper insulating layer is on the blocking layer. An upper interconnection is on the upper insulating layer. An upper plug is connected to the upper interconnection and a corresponding one of the plurality of MTJ structures and extends into the upper insulating layer and the blocking layer. The blocking layer includes a material having a higher absorbance constant than the upper insulating layer.

A semiconductor device includes a dual layer top contact upon a MTJ stack. The dual layer top contact includes lower contact and upper contact. The lower contact may be wider and/or shallower relative to the upper contact. This wide and/or shallow geometry of the lower contact may decrease the propensity for over etching, during the formation of the upper contact, opening downward into the MTJ stack and may therefore prevent undesired shorting of the MTJ stack. Further, the lower contact may further protect the MTJ stack even when the upper contact is misaligned to the MTJ stack.

A memory device includes a perpendicular magnetic tunnel junction (pMTJ) stack, between a bottom electrode and a top electrode. In an embodiment, the pMTJ includes a fixed magnet, a tunnel barrier above the fixed magnet and a free magnet structure on the tunnel barrier. The free magnet structure includes a first free magnet on the tunnel barrier and a second free magnet above the first free magnet, wherein at least a portion of the free magnet proximal to an interface with the free magnet includes a transition metal. The free magnet structure having a transition metal between the first and the second free magnets advantageously improves the switching efficiency of the MTJ, while maintaining a thermal stability of at least 50 kT.

A tunneling magnetoresistance (TMR) device has an improved seed layer for the lower or first ferromagnetic layer that eliminates the need for boron in the two ferromagnetic layers. The seed layer, for example a RuAl alloy, has a B2 crystalline structure with (001) texture when deposited on an amorphous pre-seed layer, meaning that the (001) plane is parallel to the surface of the TMR device substrate. The subsequently deposited first ferromagnetic layer, like a CoFe alloy, and the tunneling barrier layer, typically MgO, inherit the (001) texture of the seed layer.