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: 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: The invention includes deposition apparatuses having reflectors with rugged reflective surfaces configured to disperse light reflected therefrom, and/or having dispersers between lamps and a substrate. The invention also includes optical methods for utilization within a deposition apparatus for assessing the alignment of a substrate within the apparatus and/or for assessing the thickness of a layer of material deposited within the apparatus.

Abstract: The invention includes deposition apparatuses having reflectors with rugged reflective surfaces configured to disperse light reflected therefrom, and/or having dispersers between lamps and a substrate. The invention also includes optical methods for utilization within a deposition apparatus for assessing the alignment of a substrate within the apparatus and/or for assessing the thickness of a layer of material deposited within the apparatus.

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: 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: 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: This invention includes substrate susceptors which receive substrates to be deposited upon. In one implementation, a substrate susceptor includes a body having a substrate receiving side. The substrate receiving side has a face having a substrate receiving recess formed therein. The recess has an outer peripheral sidewall. At least three projections extend outwardly from a portion of the face. The projections respectively comprise a radially inner sidewall which extends outwardly from the recess outer peripheral sidewall to a projection upper surface. Other aspects and implementations are contemplated.

Abstract: This invention includes substrate susceptors which receive substrates to be deposited upon. In one implementation, a substrate susceptor includes a body having a substrate receiving side. The substrate receiving side has a face having a substrate receiving recess formed therein. The recess has an outer peripheral sidewall. At least three projections extend outwardly from a portion of the face. The projections respectively comprise a radially inner sidewall which extends outwardly from the recess outer peripheral sidewall to a projection upper surface. Other aspects and implementations are contemplated.

Abstract: This invention includes substrate susceptors which receive substrates to be deposited upon. In one implementation, a substrate susceptor includes a body having a substrate receiving side. The substrate receiving side has a face having a substrate receiving recess formed therein. The recess has an outer peripheral sidewall. At least three projections extend outwardly from a portion of the face. The projections respectively comprise a radially inner sidewall which extends outwardly from the recess outer peripheral sidewall to a projection upper surface. Other aspects and implementations are contemplated.

Abstract: The invention includes methods of forming metal silicide. A layer consisting essentially of one or more metal nitrides is formed directly against a silicon-containing region. A layer comprising one or more metals is formed over the one or more metal nitrides. Silicon is transferred from the silicon-containing region, through the one or more metal nitrides, and to the one or more metals to convert at least some of the one or more metals into metal silicides. In particular aspects, titanium is formed over tantalum nitride, and the silicon is transferred into the titanium to convert the titanium into titanium silicide. The invention also includes semiconductor constructions having a layer consisting essentially of titanium silicide directly against a layer consisting essentially of tantalum nitride.

Abstract: Systems and methods for depositing materials onto a microfeature workpiece are disclosed herein. In one embodiment, a system includes a first deposition chamber, a gas distributor carried by the first deposition chamber, a second deposition chamber operably coupled to the first deposition chamber, an energy source, and a workpiece support movable between the first and second deposition chambers. The energy source is configured to generate a plasma energy and direct the plasma energy toward a plasma zone in the second deposition chamber. The system may also include a barrier positioned in the second deposition chamber to divide the plasma zone into a first zone and a second zone. The barrier is configured to selectively control the movement of ions from the first zone to the second zone.

Abstract: The invention provides an magnetic memory element having improved switching properties and zero field offset, and a manufacturing method thereof. The element comprises a first magnetic layer overlying a conductive layer and a nonmagnetic layer overlying the first magnetic layer. Next, a second magnetic layer is provided over the nonmagnetic layer, wherein the second magnetic layer comprises an antiferromagnetic layer overlying a ferromagnetic free layer to apply a small bias to the ferromagnetic free layer. Then, the first magnetic, nonmagnetic and second magnetic layers are patterned to form the memory element.

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 common pinned layer is shared by multiple memory cells in an MRAM device. The common pinned layer includes a plurality of domain wall traps that prevent the formation of domain walls within a region of the common pinned layer corresponding to a given memory cell. Therefore, the memory cells can advantageously be formed such that the domain walls, to the extent they exist, fall between (rather than within) the memory cells, thereby improving the performance of the MRAM device.

Abstract: A common pinned layer is shared by multiple memory cells in an MRAM device. The common pinned layer includes a plurality of domain wall traps that prevent the formation of domain walls within a region of the common pinned layer corresponding to a given memory cell. Therefore, the memory cells can advantageously be formed such that the domain walls, to the extent they exist, fall between (rather than within) the memory cells, thereby improving the performance of the MRAM device.

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 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 relates to methods and apparatus that allow data to be stored in a magnetic memory cell, such as a giant magneto-resistance (GMR) cell, of a magnetoresistive random access memory (MRAM). Embodiments of the invention advantageously wind a word line around a magnetic memory cell to increase the magnetic field induced by the word line. The word line can be formed by connecting a segment in a first layer to a segment in a second layer with the memory cell disposed between the first layer and the second layer. Advantageously, embodiments of the invention can include relatively narrow magnetic memory cells, and/or bit lines, have relatively high write selectivity, and can use relatively low word currents to store data. In one MRAM, current is passed through a word line by allowing current to flow through a corresponding word row line and a corresponding word column line.