Abstract: An apparatus for manufacturing a display device includes a plurality of working tables, a plurality of arm modules, and a rotator. The plurality of working tables are spaced apart from each other in a first direction and are configured to support a target board. The plurality of arm modules are arranged in the first direction and spaced apart from the plurality of working tables in a second direction intersecting the first direction. The rotator is connected to the plurality of arm modules and configured to rotate about a rotation axis extending in the first direction.

Abstract: An apparatus for manufacturing a display device includes a plurality of working tables, a plurality of arm modules, and a rotator. The plurality of working tables are spaced apart from each other in a first direction and are configured to support a target board. The plurality of arm modules are arranged in the first direction and spaced apart from the plurality of working tables in a second direction intersecting the first direction. The rotator is connected to the plurality of arm modules and configured to rotate about a rotation axis extending in the first direction.

Abstract: The present invention relates to a Candida tropicalis cell line, which comprises a mutant gene, having improved tolerance for cytotoxicity of stromal cells, and a method for producing dicarboxylic acid using the Candida tropicalis cell line. The Candida tropicalis cell line for producing dicarboxylic acid developed according to the present invention has improved tolerance for existing stromal toxicity as well as significantly improved efficiency for producing dicarboxylic acid compared to existing cell lines, thus can be used in biological production of dicarboxylic acid and is expected to have high industrial utility.

Abstract: A switching element includes a lower barrier electrode on a substrate, a switching pattern on the lower barrier electrode, and an upper barrier electrode on the switching pattern. The lower barrier electrode includes a first lower barrier electrode layer, and a second lower barrier electrode layer interposed between the first lower barrier electrode layer and the switching pattern and whose density is different from the density of the first lower barrier electrode.

Abstract: The present invention relates to a Candida tropicalis cell line, which comprises a mutant gene, having improved tolerance for cytotoxicity of stromal cells, and a method for producing dicarboxylic acid using the Candida tropicalis cell line. The Candida tropicalis cell line for producing dicarboxylic acid developed according to the present invention has improved tolerance for existing stromal toxicity as well as significantly improved efficiency for producing dicarboxylic acid compared to existing cell lines, thus can be used in biological production of dicarboxylic acid and is expected to have high industrial utility.

Abstract: A semiconductor device includes a first memory cell, a second memory cell, a first capping film, and a second capping film. The first memory cell includes a first ovonic threshold switch (OTS) on a first phase change memory. The second memory cell includes a second OTS on a second phase change memory. The first capping film is on side surfaces of the first and second memory cells. The second capping film is on the first capping film and fills a space between the first and second memory cells.

Abstract: A switching element includes a lower barrier electrode on a substrate, a switching pattern on the lower barrier electrode, and an upper barrier electrode on the switching pattern. The lower barrier electrode includes a first lower barrier electrode layer, and a second lower barrier electrode layer interposed between the first lower barrier electrode layer and the switching pattern and whose density is different from the density of the first lower barrier electrode.

Abstract: A switching element includes a lower barrier electrode on a substrate, a switching pattern on the lower barrier electrode, and an upper barrier electrode on the switching pattern. The lower barrier electrode includes a first lower barrier electrode layer, and a second lower barrier electrode layer interposed between the first lower barrier electrode layer and the switching pattern and whose density is different from the density of the first lower barrier electrode.

Abstract: Forming a semiconductor device that includes a memory cell array may include performing a switching firing operation on one or more memory cells of the memory array to cause a threshold voltage distribution associated with threshold switching devices in the memory cells to be reduced. The switching device firing operation may be performed such that the threshold voltage distribution is reduced while maintaining the one or more threshold switching devices in the amorphous state. Performing the switching device firing operation on a threshold switching device may include heating the threshold switching device, applying a voltage to the threshold switching device, applying a current to the threshold switching device, some combination thereof, or the like.

Abstract: A semiconductor device includes a first memory cell, a second memory cell, a first capping film, and a second capping film. The first memory cell includes a first ovonic threshold switch (OTS) on a first phase change memory. The second memory cell includes a second OTS on a second phase change memory. The first capping film is on side surfaces of the first and second memory cells. The second capping film is on the first capping film and fills a space between the first and second memory cells.

Abstract: A variable resistance memory device includes first conductive lines positioned above a substrate. Each of the first conductive lines extends in a first direction and a second direction. Second conductive lines extend in the first direction and the second direction. The second conductive lines are positioned above the first conductive lines. A memory is positioned between the first and second conductive lines. The memory unit overlaps the first and second conductive lines in a third direction. The memory unit includes a first electrode, a variable resistance pattern positioned on the first electrode, and a second electrode positioned on the variable resistance pattern. A selection pattern is positioned on each memory unit. A third electrode is positioned above the selection pattern. The third electrode is in direct contact with a lower surface of each of the second conductive lines.

Abstract: A switching element includes a lower barrier electrode on a substrate, a switching pattern on the lower barrier electrode, and an upper barrier electrode on the switching pattern. The lower barrier electrode includes a first lower barrier electrode layer, and a second lower barrier electrode layer interposed between the first lower barrier electrode layer and the switching pattern and whose density is different from the density of the first lower barrier electrode.

Abstract: Forming a semiconductor device that includes a memory cell array may include performing a switching firing operation on one or more memory cells of the memory array to cause a threshold voltage distribution associated with threshold switching devices in the memory cells to be reduced. The switching device firing operation may be performed such that the threshold voltage distribution is reduced while maintaining the one or more threshold switching devices in the amorphous state. Performing the switching device firing operation on a threshold switching device may include heating the threshold switching device, applying a voltage to the threshold switching device, applying a current to the threshold switching device, some combination thereof, or the like.

Abstract: Forming a semiconductor device that includes a memory cell array may include performing a switching firing operation on one or more memory cells of the memory array to cause a threshold voltage distribution associated with threshold switching devices in the memory cells to be reduced. The switching device firing operation may be performed such that the threshold voltage distribution is reduced while maintaining the one or more threshold switching devices in the amorphous state. Performing the switching device firing operation on a threshold switching device may include heating the threshold switching device, applying a voltage to the threshold switching device, applying a current to the threshold switching device, some combination thereof, or the like.

Abstract: A variable resistance memory device includes first conductive lines positioned above a substrate. Each of the first conductive lines extends in a first direction and a second direction. Second conductive lines extend in the first direction and the second direction. The second conductive lines are positioned above the first conductive lines. A memory is positioned between the first and second conductive lines. The memory unit overlaps the first and second conductive lines in a third direction. The memory unit includes a first electrode, a variable resistance pattern positioned on the first electrode, and a second electrode positioned on the variable resistance pattern. A selection pattern is positioned on each memory unit. A third electrode is positioned above the selection pattern. The third electrode is in direct contact with a lower surface of each of the second conductive lines.

Abstract: A method of manufacturing a magnetoresistive random access memory device, the method including forming a memory structure on a substrate, the memory structure including a lower electrode, a magnetic tunnel junction structure, and an upper electrode sequentially stacked; forming a first capping layer to cover a surface of the memory structure by a deposition process using a plasma under first conditions; and forming a second capping layer on the first capping layer by a deposition process using a plasma under second conditions different from the first conditions.

Abstract: A variable resistance memory device includes first conductive lines positioned above a substrate. Each of the first conductive lines extends in a first direction and a second direction. Second conductive lines extend in the first direction and the second direction. The second conductive lines are positioned above the first conductive lines. A memory is positioned between the first and second conductive lines. The memory unit overlaps the first and second conductive lines in a third direction. The memory unit includes a first electrode, a variable resistance pattern positioned on the first electrode, and a second electrode positioned on the variable resistance pattern. A selection pattern is positioned on each memory unit. A third electrode is positioned above the selection pattern. The third electrode is in direct contact with a lower surface of each of the second conductive lines.

Abstract: A variable resistance memory device may include: a first electrode layer; a selection device layer on the first electrode layer, the selection device layer including a chalcogenide switching material consisting essentially of germanium (Ge), selenium (Se), and antimony (Sb), wherein a content of the Ge is less than a content of the Se based on an atomic weight; a second electrode layer on the selection device layer; a variable resistance layer on the second electrode layer, the variable resistance layer including a chalcogenide material; and a third electrode layer on the variable resistance layer.

Abstract: A semiconductor device includes a first memory cell, a second memory cell, a first capping film, and a second capping film. The first memory cell includes a first ovonic threshold switch (OTS) on a first phase change memory. The second memory cell includes a second OTS on a second phase change memory. The first capping film is on side surfaces of the first and second memory cells. The second capping film is on the first capping film and fills a space between the first and second memory cells.

Abstract: A method of manufacturing a magnetoresistive random access memory device, the method including forming a memory structure on a substrate, the memory structure including a lower electrode, a magnetic tunnel junction structure, and an upper electrode sequentially stacked; forming a first capping layer to cover a surface of the memory structure by a deposition process using a plasma under first conditions; and forming a second capping layer on the first capping layer by a deposition process using a plasma under second conditions different from the first conditions.