Abstract: A metal manganese oxide buffer layer is used to seed a barrier layer in a magnetic tunnel junction memory element having pinned and free magnetic layers. An alumina tunnel barrier layer is formed on the oxidized metal manganese layer with the barrier layer and oxidized metal manganese layer being between the pinned or free ferromagnetic layers.

Abstract: The invention includes semiconductor processing methods in which openings are formed to extend into a semiconductor substrate, and the substrate is then annealed around the openings to form cavities. The substrate is etched to expose the cavities, and the cavities are substantially filled with insulative material. The semiconductor substrate having the filled cavities therein can be utilized as a semiconductor-on-insulator-type structure, and transistor devices can be formed to be supported by the semiconductor material and to be over the cavities. In some aspects, the transistor devices have channel regions over the filled cavities, and in other aspects the transistor devices have source/drain regions over the filled cavities. The transistor devices can be incorporated into dynamic random access memory, and can be utilized in electronic systems.

Abstract: The invention includes semiconductor processing methods in which openings are formed to extend into a semiconductor substrate, and the substrate is then annealed around the openings to form cavities. The substrate is etched to expose the cavities, and the cavities are substantially filled with insulative material. The semiconductor substrate having the filled cavities therein can be utilized as a semiconductor-on-insulator-type structure, and transistor devices can be formed to be supported by the semiconductor material and to be over the cavities. In some aspects, the transistor devices have channel regions over the filled cavities, and in other aspects the transistor devices have source/drain regions over the filled cavities. The transistor devices can be incorporated into dynamic random access memory, and can be utilized in electronic systems.

Abstract: The invention includes a method of forming a semiconductor construction, such as an MRAM construction. A block is formed over a semiconductor substrate. First and second layers are formed over the block, and over a region of the substrate proximate the block. The first and second layers are removed from over the block while leaving portions of the first and second layers over the region proximate the block. At least some of the first layer is removed from under the second layer to form a channel over the region proximate the block. A material, such as a soft magnetic material, is provided within the channel. The invention also includes semiconductor constructions.

Abstract: The invention includes a method of forming a semiconductor construction, such as an MRAM construction. A block is formed over a semiconductor substrate. First and second layers are formed over the block, and over a region of the substrate proximate the block. The first and second layers are removed from over the block while leaving portions of the first and second layers over the region proximate the block. At least some of the first layer is removed from under the second layer to form a channel over the region proximate the block. A material, such as a soft magnetic material, is provided within the channel. The invention also includes semiconductor constructions.

Abstract: A magneto-resistive memory comprising magneto-resistive memory cells is disclosed, comprising a pinned magnetic layer and a free magnetic layer. The two magnetic layers are formed having widened regions at the ends of the layers. As such, the shape made out by the magneto-resisitve memory, from a top-view perspective, is wide at the ends and narrower at the mid-, forming an I shape in one preferred embodiment. The end portions of the free magnetic layer are allowed to magnetically couple to the end portions of the pinned magnetic layer such that magnetic coupling is shifted to these widened regions and coupling in the mid-portion between the widened regions is minimized. Thus, the influence of the pinned magnetic layer on the magnetization orientation of the mid-portion of the free magnetic layer is substantially eliminated, allowing for increased predictability in switching behavior and increased write selectivity of memory cells.

Abstract: In one implementation, a substrate susceptor for receiving a semiconductor substrate for selective epitaxial silicon-comprising depositing thereon, where the depositing comprises measuring emissivity of the susceptor from at least one susceptor location in a non-contacting manner, includes a body having a front substrate receiving side, a back side, and a peripheral edge. At least one susceptor location from which emissivity is to be measured is received on at least one of the front substrate receiving side, the back side, and the edge. Such at least one susceptor location comprises an outermost surface comprising a material upon which selective epitaxial silicon will not deposit upon during selective epitaxial silicon depositing on a semiconductor substrate received by the susceptor for at least an initial thickness of epitaxial silicon depositing on said substrate. Other aspects and implementations are contemplated.

Abstract: Magneto-resistive random access memory elements include a ferromagnetic layer having uniaxial anisotropy provided by elongate structures formed in the ferromagnetic film. The magnetic dipole aligns with the long axis of each structure. The structures can be formed in a variety of ways. For example, the ferromagnetic film can be applied to a seed layer having a textured surface. Alternatively, the ferromagnetic film can be stressed to generate the textured structure. Chemical mechanical polishing also can be used to generated the structures.

Abstract: The present invention provides atomic layer deposition systems and methods that include at least one compound of the formula (Formula I): Ta(NR1)(NR2R3)3, wherein each R1, R2, and R3 is independently hydrogen or an organic group, with the proviso that at least one of R1, R2, and R3 is a silicon-containing organic group. Such systems and methods can be useful for depositing tantalum silicon nitride layers on substrates.

Abstract: The invention relates to improving the switching reliability of a magnetic memory cell in a magnetic random access memory (MRAM). Embodiments of the invention add an antiferromagnet to a magnetic memory cell. An antiferromagnetic layer can be formed adjacent to a soft layer in the MRAM on a side of the soft layer that is opposite to a hard layer of the MRAM. One embodiment further includes an additional interlayer of non-antiferromagnetic material between the antiferromagnetic layer and the soft layer.

Abstract: The invention includes semiconductor processing methods in which openings are formed to extend into a semiconductor substrate, and the substrate is then annealed around the openings to form cavities. The substrate is etched to expose the cavities, and the cavities are substantially filled with insulative material. The semiconductor substrate having the filled cavities therein can be utilized as a semiconductor-on-insulator-type structure, and transistor devices can be formed to be supported by the semiconductor material and to be over the cavities. In some aspects, the transistor devices have channel regions over the filled cavities, and in other aspects the transistor devices have source/drain regions over the filled cavities. The transistor devices can be incorporated into dynamic random access memory, and can be utilized in electronic systems.

Abstract: An MRAM device includes an array of magnetic memory cells having an upper conductive layer and a lower conductive layer separated by a barrier layer. To reduce the likelihood of electrical shorting across the barrier layers of the memory cells, spacers can be formed around the upper conductive layer and, after the layers of the magnetic memory cells have been etched, the memory cells can be oxidized to transform any conductive particles that are deposited along the sidewalls of the memory cells as byproducts of the etching process into nonconductive particles. Alternatively, the lower conductive layer can be repeatedly subjected to partial oxidation and partial etching steps such that only nonconductive particles can be thrown up along the sidewalls of the memory cells as byproducts of the etching process.

Abstract: The invention includes deposition apparatuses configured to monitor the temperature of a semiconductor wafer substrate by utilizing conduits which channel radiation from the substrate to a detector/signal processor system. In particular aspects, the temperature of the substrate can be measured while the substrate is spinning within a reaction chamber. The invention also includes deposition apparatuses in which flow of mixed gases is controlled by mass flow controllers provided downstream of the location where the gases are mixed and/or where flow of gases is measured with mass flow measurement devices provided downstream of the location where the gases are mixed. Additionally, the invention encompasses deposition apparatuses in which mass flow controllers and/or mass flow measurement devices are provided upstream of a header which splits a source gas into multiple paths directed toward multiple different reaction chambers.

Abstract: A MRAM cell structure is disclosed as containing an additional ferromagnetic layer and coupling layer between the third ferromagnetic layer and the anti-ferromagnetic layer. The additional ferromagnetic layer affects the demagnetization field to which the free layer is exposed, thereby reducing any bias introduced to the free layer. Further, by adjusting the thickness of the additional ferromagnetic layer, the effects of Neel coupling on the free layer are reduced.

Abstract: The invention relates to improving the switching reliability of a magnetic memory cell in a magnetic random access memory (MRAM). Embodiments of the invention add an antiferromagnet to a magnetic memory cell. An antiferromagnetic layer can be formed adjacent to a soft layer in the MRAM on a side of the soft layer that is opposite to a hard layer of the MRAM. One embodiment further includes an additional interlayer of non-antiferromagnetic material between the antiferromagnetic layer and the soft layer.

Abstract: The invention includes methods of forming titanium-containing materials, such as, for example, titanium silicide. The invention can use alternating cycles of titanium halide precursor and one or more reductants to form the titanium-containing material. For instance, the invention can utilize alternating cycles of titanium tetrachloride and activated hydrogen to form titanium silicide on a surface of a silicon-containing substrate.

Abstract: An optical assay device for the detection of an analyte of interest in a sample comprising a support containing channels, an optically functional layer positioned on the support such that the optically functional layer and the support allow for laminar flow of the sample through layers of the device, an attachment layer positioned on the optically functional layer, and an analyte specific receptive layer positioned on the attachment layer.

Abstract: The invention includes methods of depositing elemental silicon-comprising materials over a semiconductor substrate, and methods of cleaning an internal wall of a chamber. In one implementation, a semiconductor substrate is positioned within a chamber for deposition. The chamber comprises an infrared radiation transparent wall. An elemental silicon-comprising material is deposited on the semiconductor substrate. During such depositing, a deposit is formed on the infrared radiation transparent wall within the chamber. After such depositing, a plasma is generated within the chamber with a cleaning gas from at least one plasma generating electrode received external of the chamber proximate the infrared radiation transparent wall effective to remove at least some of the deposit from the infrared radiation transparent wall within the chamber. Other aspects and implementations are contemplated.

Abstract: The present invention is generally directed to a method of forming a pseudo SOI substrate and semiconductor devices. In one illustrative embodiment, the method comprises forming a plurality of trenches in a semiconducting substrate comprised of silicon, each of the trenches having a depth, forming a layer of insulating material within each of the plurality of trenches, the layer of insulating material having a thickness that is less than the depth of the trenches, and performing an anneal process on the substrate in a hydrogen environment to cause the silicon substrate material to merge above the layer of insulating material within the plurality of trenches to thereby define a pseudo SOI substrate.

Abstract: In one implementation, a substrate susceptor for receiving a semiconductor substrate for selective epitaxial silicon-comprising depositing thereon, where the depositing comprises measuring emissivity of the susceptor from at least one susceptor location in a non-contacting manner, includes a body having a front substrate receiving side, a back side, and a peripheral edge. At least one susceptor location from which emissivity is to be measured is received on at least one of the front substrate receiving side, the back side, and the edge. Such at least one susceptor location comprises an outermost surface comprising a material upon which selective epitaxial silicon will not deposit upon during selective epitaxial silicon depositing on a semiconductor substrate received by the susceptor for at least an initial thickness of epitaxial silicon depositing on said substrate. Other aspects and implementations are contemplated.