A ferroelectric device includes a first electrode and a second electrode that each comprise one or more electrically conductive layers. The ferroelectric device also includes a layer of ferroelectric material disposed between, and in electrical communication with, the first electrode and the second electrode. The first electrode and/or the second electrode include a recessed region and the layer of ferroelectric material includes a corresponding region of increased thickness that resists polarity changes. For example, a programming signal that is applied across the first and second electrodes may change a polarity of one or more other portions of the layer of ferroelectric material without changing a polarity of a portion of the layer of ferroelectric material that is proximate to the region of increased thickness. A corresponding method is also disclosed herein.

The present disclosure provides a method for fabricating a semiconductor device. The method includes the operations below. A magnetic tunneling junction (MTJ) is formed on a substrate. A first dielectric layer is formed around the MTJ. A first metal interconnection is formed adjacent to the MTJ. A second dielectric layer is formed over the first dielectric layer. The second dielectric layer is removed to form an opening. A metal line is formed in the opening to electrically connect the MTJ and the first metal interconnection.

The present disclosure provides a semiconductor structure including a substrate, a transistor region having a gate over the substrate and a doped region at least partially in the substrate, a first metal layer over the transistor region, and a magnetic tunneling junction (MTJ) between the transistor region and the first metal layer. The present disclosure provides a method for manufacturing a semiconductor structure, including forming a transistor region over a substrate, the transistor region comprising a gate and a doped region, forming a magnetic tunneling junction (MTJ) over the transistor region, electrically coupling to the transistor region, and forming a first metal layer over the MTJ, electrically coupling to the MTJ and the transistor region.

The disclosed technology generally relates to magnetoresistive devices, and more particularly to a magnetic tunnel junction (MTJ) device formed in an interconnection structure, and to a method of integrating the (MTJ) device in the interconnection structure. According to an aspect, a device includes a first interconnection level including a first dielectric layer and a first set of conductive paths arranged in the first dielectric layer, a second interconnection level arranged on the first connection level and including a second dielectric layer and a second set of conductive paths arranged in the second dielectric layer, and a third interconnection level arranged on the second interconnection level and including a third dielectric layer and a third set of conductive paths arranged in the third dielectric layer. The device additionally includes a magnetic tunnel junction (MTJ) device including a bottom layer, a top layer and an MTJ structure arranged between the bottom layer and the top layer, wherein the bottom layer is connected to a bottom layer contact portion of the first set of conductive paths and the top layer is connected to a top layer contact portion of the second or third set of conductive paths. The device further includes a multi-level via extending through the second dielectric layer and the third dielectric layer, between a first via contact portion of the first set of conductive paths and a second via contact portion of the third set of conductive paths, wherein a height of the MTJ device corresponds to, or is less than, a height of the multi-level via.

A method of forming a memory device that in one embodiment may include forming a magnetic tunnel junction on a first electrode using an electrically conductive mask and subtractive etch method. Following formation of the magnetic tunnel junction, at least one dielectric layer is deposited to encapsulate the magnetic tunnel junction. Ion beam etching/Ion beam milling may then remove the portion of the at least one dielectric layer that is present on the electrically conductive mask, wherein a remaining portion of the at least one dielectric layer is present over the first electrode. A second electrode may then be formed in contact with the electrically conductive mask.

The disclosed technology generally relates to magnetic memory devices, and more particularly to spin transfer torque magnetic random access memory (STT-MRAM) devices having a magnetic tunnel junction (MTJ), and further relates to methods of fabricating the STT-MRAM devices. In an aspect, a magnetoresistive random access memory (MRAM) device has a magnetic tunnel junction (MTJ). The MTJ includes a magnetic reference layer including CoFeB, a magnetic free layer comprising CoFeB, and a barrier layer including MgO. The barrier layer is interposed between the magnetic reference layer and the magnetic free layer. The barrier layer has a thickness adapted to tunnel electrons between the magnetic reference layer and the magnetic free layer sufficient to cause a change in the magnetization direction of the variable magnetization under a bias. The MTJ further comprises a buffer layer comprising one or more of Co, Fe, CoFe and CoFeB, where the buffer layer is doped with one or both of C and N.

A method of forming a memory device that in one embodiment may include forming a magnetic tunnel junction on a first electrode using an electrically conductive mask and subtractive etch method. Following formation of the magnetic tunnel junction, at least one dielectric layer is deposited to encapsulate the magnetic tunnel junction. Ion beam etching/Ion beam milling may then remove the portion of the at least one dielectric layer that is present on the electrically conductive mask, wherein a remaining portion of the at least one dielectric layer is present over the first electrode. A second electrode may then be formed in contact with the electrically conductive mask.

A semiconductor device and a method of forming the same are provided. The method includes forming a bottom electrode layer over a substrate. A magnetic tunnel junction (MTJ) layers are formed over the bottom electrode layer. A top electrode layer is formed over the MTJ layers. The top electrode layer is patterned. After patterning the top electrode layer, one or more process cycles are performed on the MTJ layers and the bottom electrode layer. A patterned top electrode layer, patterned MTJ layers and a patterned bottom electrode layer form MTJ structures. Each of the one or more process cycles includes performing an etching process on the MTJ layers and the bottom electrode layer for a first duration and performing a magnetic treatment on the MTJ layers and the bottom electrode layer for a second duration.

Disclosed is a method of fabricating a magnetic memory device. The method of a fabricating a magnetic memory device includes forming an interlayer dielectric layer on a substrate, forming a sacrificial pattern in the interlayer dielectric layer, forming a magnetic tunnel junction pattern on the sacrificial pattern, after forming the magnetic tunnel junction pattern, selectively removing the sacrificial pattern to form a bottom contact region in the interlayer dielectric layer, and forming a bottom contact in the bottom contact region.

A memory device includes a semiconductor device on a wafer. The semiconductor device includes a gate structure, a first source/drain region, and a second source/drain region. The gate structure is on the first side of the wafer. The first source/drain region is also on the first side of the wafer, and contacts a first end of the gate structure. The second source/drain region is on the second side of the wafer and extends into the first side to contact a second end of the gate structure. The memory device further includes a memory storage element on the second side of the wafer. The memory storage element contacts the second source/drain region.