Abstract: A sputtering apparatus including a chamber, a gas supply configured to supply the chamber with a first gas and a second inert gas, the first inert gas and the second inert gas having a first evaporation point and second evaporation point, respectively, a plurality of sputter guns in an upper portion of the chamber, a chuck in a lower portion of the chamber and facing the sputter guns, the chuck configured to accommodate a substrate thereon, and a cooling unit connected to a lower portion of the chuck, the cooling unit configured to cool the chuck to a temperature less than the first evaporation point and greater than the second evaporation point, and a method of fabricating a magnetic memory device may be provided.

Abstract: A magnetic memory device, a method for manufacturing a magnetic memory device, and a substrate treating apparatus, the device including a substrate including a first memory region and a second memory region; a first magnetic tunnel junction pattern on the first memory region, the first magnetic tunnel junction pattern including a first free pattern and a first oxide pattern on the first free pattern; and a second magnetic tunnel junction pattern on the second memory region, the second magnetic tunnel junction pattern including a second free pattern and a second oxide pattern on the second free pattern, wherein a ratio of a thickness of the first oxide pattern to a thickness of the first free pattern is different from a ratio of a thickness of the second oxide pattern to a thickness of the second free pattern.

Abstract: A magnetic memory device includes a conductive line extending in a first direction, a bottom electrode provided on a portion of a bottom surface of the conductive line, a free layer and a pinned layer stacked on the conductive line, a spacer layer between the free layer and the pinned layer, and a top electrode provided on a portion of a top surface of the pinned layer. The conductive line, the free layer, the pinned layer and the spacer layer have side surfaces perpendicular to the first direction, and the side surfaces are aligned with each other.

Abstract: In a method of manufacturing an MRAM device, first and second lower electrodes may be formed on first and second regions, respectively, of a substrate. First and second MTJ structures having different switching current densities from each other may be formed on the first and second lower electrodes, respectively. First and second upper electrodes may be formed on the first and second MTJ structures, respectively.

Abstract: Memory devices and methods of forming the same include forming a memory stack over a bottom electrode. The memory stack has a free magnetic layer formed on the tunnel barrier layer. A first boron-segregating layer is formed directly on the free magnetic layer. An anneal is performed to cause boron to leave the free magnetic layer at an interface with the first boron-segregating layer. A top electrode is formed over the memory stack.

Abstract: In a method of manufacturing an MRAM device, first and second lower electrodes may be formed on first and second regions, respectively, of a substrate. First and second MTJ structures having different switching current densities from each other may be formed on the first and second lower electrodes, respectively. First and second upper electrodes may be formed on the first and second MTJ structures, respectively.

Abstract: Disclosed is a magnetic memory device including a line pattern on a substrate, a magnetic tunnel junction pattern on the line pattern, and an upper conductive line that is spaced apart from the line pattern across the magnetic tunnel junction pattern and is connected to the magnetic tunnel junction pattern. The line pattern provides the magnetic tunnel junction pattern with spin-orbit torque. The line pattern includes a chalcogen-based topological insulator.

Abstract: The methods of manufacturing an MRAM device and MRAM devices are provided. The methods may include forming a first electrode on an upper surface of a substrate, forming a first magnetic layer on the first electrode, forming a tunnel barrier structure on the first magnetic layer, forming a second magnetic layer on the tunnel barrier structure, and forming a second electrode on the second magnetic layer. The tunnel barrier structure may include a first tunnel barrier layer and a second tunnel barrier layer that are sequentially stacked on the first magnetic layer and may have different resistivity distributions from each other along a horizontal direction that may be parallel to the upper surface of the substrate.

Abstract: Semiconductor devices may include a first memory cell on a substrate and a second memory cell on the substrate and adjacent to the first memory cell. The first memory cell may include a first reference layer, a first storage layer, a first tunnel layer between the first reference layer and the first storage layer, and a first spin-orbit torque (SOT) line in contact with the first storage layer. The second memory cell may include a second reference layer, a second storage layer, a second tunnel layer between the second reference layer and the second storage layer, a second SOT line adjacent to the second storage layer, and an enhancing layer between the second storage layer and the second SOT line.

Abstract: The methods of manufacturing an MRAM device and MRAM devices are provided. The methods may include forming a first electrode on an upper surface of a substrate, forming a first magnetic layer on the first electrode, forming a tunnel barrier structure on the first magnetic layer, forming a second magnetic layer on the tunnel barrier structure, and forming a second electrode on the second magnetic layer. The tunnel barrier structure may include a first tunnel barrier layer and a second tunnel barrier layer that are sequentially stacked on the first magnetic layer and may have different resistivity distributions from each other along a horizontal direction that may be parallel to the upper surface of the substrate.

Abstract: Provided are process control methods and process control systems. The method includes performing a deposition process on a lot defined by a group of a plurality of wafers, performing a measurement process on the lot to obtain a measured value with respect to at least one wafer among the plurality of wafers, producing a target value of a factor of a process condition in the deposition process by using a difference between the measured value and a reference value, and providing an input value of the factor with respect to a subsequent lot based on the target value. The operation of providing the input value of the factor includes obtaining a previous target value of the factor previously produced with respect to at least one previous lot, and providing a weighted average of the previous target value and the target value as the input value.

Abstract: A magnetic memory device, a method for manufacturing a magnetic memory device, and a substrate treating apparatus, the device including a substrate including a first memory region and a second memory region; a first magnetic tunnel junction pattern on the first memory region, the first magnetic tunnel junction pattern including a first free pattern and a first oxide pattern on the first free pattern; and a second magnetic tunnel junction pattern on the second memory region, the second magnetic tunnel junction pattern including a second free pattern and a second oxide pattern on the second free pattern, wherein a ratio of a thickness of the first oxide pattern to a thickness of the first free pattern is different from a ratio of a thickness of the second oxide pattern to a thickness of the second free pattern.

Abstract: A double magnetic tunnel junction includes a bottom reference layer having a first fixed magnetization and a first thickness and formed from at least one material. A first tunnel barrier is on the bottom reference layer. A free layer is on the first tunnel barrier and has a changeable magnetization. A second tunnel barrier is on the free layer. A multilayered top reference layer is formed on the second tunnel barrier having a second fixed magnetization that is opposite to the first fixed magnetization and a second thickness that is smaller than the first thickness, and equal to or greater than the third thickness.

Abstract: The methods of manufacturing an MRAM device and MRAM devices are provided. The methods may include forming a first electrode on an upper surface of a substrate, forming a first magnetic layer on the first electrode, forming a tunnel barrier structure on the first magnetic layer, forming a second magnetic layer on the tunnel barrier structure, and forming a second electrode on the second magnetic layer. The tunnel barrier structure may include a first tunnel barrier layer and a second tunnel barrier layer that are sequentially stacked on the first magnetic layer and may have different resistivity distributions from each other along a horizontal direction that may be parallel to the upper surface of the substrate.

Abstract: Embodiments of the invention are directed to a magnetic tunnel junction (MTJ) storage element that includes a reference layer, a tunnel barrier and a free layer on an opposite side of the tunnel barrier layer from the reference layer. The reference layer has a fixed magnetization direction. The free layer includes a first region, a second region and a third region. The third region is formed from a third material that is configured to magnetically couple the first region and the second region. The first region is formed from a first material having a first predetermined magnetic moment, and the second region is formed from a second material having a second predetermined magnetic moment. The first predetermined magnetic moment is lower that the second predetermined magnetic moment.

Abstract: Embodiments of the invention are directed to a magnetic tunnel junction (MTJ) storage element that includes a reference layer, a tunnel barrier and a free layer on an opposite side of the tunnel barrier layer from the reference layer. The reference layer has a fixed magnetization direction. The free layer includes a first region, a second region and a third region. The third region is formed from a third material that is configured to magnetically couple the first region and the second region. The first region is formed from a first material having a first predetermined magnetic moment, and the second region is formed from a second material having a second predetermined magnetic moment. The first predetermined magnetic moment is lower that the second predetermined magnetic moment.

Abstract: In a method of manufacturing an MRAM device, first and second lower electrodes may be formed on first and second regions, respectively, of a substrate. First and second MTJ structures having different switching current densities from each other may be formed on the first and second lower electrodes, respectively. First and second upper electrodes may be formed on the first and second MTJ structures, respectively.

Abstract: Double magnetic tunnel junctions and methods of forming the same include a bottom reference layer having a first fixed magnetization and a first thickness. A first tunnel barrier is formed on the bottom reference layer. A free layer is formed on the first tunnel barrier and has a changeable magnetization. A second tunnel barrier is formed on the free layer. A top reference layer is formed on the second tunnel barrier and has a second fixed magnetization that is opposite to the first fixed magnetization and a second thickness that is significantly smaller than the first thickness.

Abstract: In a method of manufacturing an MRAM device, first and second lower electrodes may be formed on first and second regions, respectively, of a substrate. First and second MTJ structures having different switching current densities from each other may be formed on the first and second lower electrodes, respectively. First and second upper electrodes may be formed on the first and second MTJ structures, respectively.

Abstract: Memory devices and methods of forming the same include forming a memory stack over a bottom electrode. The memory stack has a free magnetic layer formed on the tunnel barrier layer. A first boron-segregating layer is formed directly on the free magnetic layer. An anneal is performed to cause boron to leave the free magnetic layer at an interface with the first boron-segregating layer. A top electrode is formed over the memory stack.