Abstract: A semiconductor device may include a conductive structure on a substrate, a contact plug on the conductive structure, and a magnetic tunnel junction structure on the contact plug. A lower surface of the contact plug may have an area greater than that of an upper surface thereof, and the contact plug may include a capping pattern at least partially covering an upper surface of the conductive structure, a conductive pattern on the capping pattern, and an amorphous metal pattern on the conductive pattern.

Abstract: A semiconductor device may include a conductive structure on a substrate, a contact plug on the conductive structure, and a magnetic tunnel junction structure on the contact plug. A lower surface of the contact plug may have an area greater than that of an upper surface thereof, and the contact plug may include a capping pattern at least partially covering an upper surface of the conductive structure, a conductive pattern on the capping pattern, and an amorphous metal pattern on the conductive pattern.

Abstract: The present disclosure relates to transgenic Caenorhabditis elegans including, in sensory neurons, Channelrhodopsin 2 (ChR2)::Green Fluorescence Protein (GFP) DNA in which the ChR2 gene and the GFP gene are linked, a method of producing the same, a method of regulating the lifespan thereof, and a method of screening an aging regulation candidate by using the same. The present disclosure may also provide an animal model for research into prevention/treatment of aging-related diseases by regulating the lifespan of an animal on a subject level and a method of screening a drug candidate for prevention/treatment of aging-related diseases.

Abstract: Methods of manufacturing a magnetic memory device including forming a lower magnetic layer, a tunnel barrier layer, and an upper magnetic layer on a substrate, forming a magnetic tunnel junction (MTJ) pattern by patterning the lower magnetic layer, the tunnel barrier layer, and the upper magnetic layer, forming a first insulating layer exposing an upper surface of the MTJ pattern, forming a polymer pattern on the exposed upper surface of the MTJ pattern, forming a second insulating layer exposing an upper surface of the polymer pattern, removing the polymer pattern to form a cavity in the second insulating layer, the cavity exposing the upper surface of the MTJ pattern, and forming a metal line by filling the cavity with a conductive metal.

Abstract: A method of manufacturing a magnetic memory device may include forming a lower magnetic layer, a tunnel barrier layer, and an upper magnetic layer on a substrate, forming a magnetic tunnel junction pattern by etching a stacked structure including the lower magnetic layer, the tunnel barrier layer, and the upper magnetic layer, forming a boron-absorption layer covering the magnetic tunnel junction pattern, and performing a heat treatment process so that boron included in the upper and lower magnetic layers may be absorbed by the boron-absorption layer. The heat treatment process may be undertaken in a gaseous atmosphere including at least one of hydrogen, oxygen, and nitrogen.

Abstract: Provided are a magnetic memory device and a method of forming the same. The magnetic memory device includes a magnetic tunnel junction pattern located on a substrate and including magnetic patterns and a tunnel barrier pattern located between the magnetic patterns, and a first crystallinity conserving pattern located on the magnetic tunnel junction pattern and having a higher crystallization temperature than the magnetic patterns. The first crystallinity conserving pattern is amorphous.

Abstract: Methods of manufacturing a magnetic memory device including forming a lower magnetic layer, a tunnel barrier layer, and an upper magnetic layer on a substrate, forming a magnetic tunnel junction (MTJ) pattern by patterning the lower magnetic layer, the tunnel barrier layer, and the upper magnetic layer, forming a first insulating layer exposing an upper surface of the MTJ pattern, forming a polymer pattern on the exposed upper surface of the MTJ pattern, forming a second insulating layer exposing an upper surface of the polymer pattern, removing the polymer pattern to form a cavity in the second insulating layer, the cavity exposing the upper surface of the MTJ pattern, and forming a metal line by filling the cavity with a conductive metal.

Abstract: A method of manufacturing a magnetic memory device may include forming a lower magnetic layer, a tunnel barrier layer, and an upper magnetic layer on a substrate, forming a magnetic tunnel junction pattern by etching a stacked structure including the lower magnetic layer, the tunnel barrier layer, and the upper magnetic layer, forming a boron-absorption layer covering the magnetic tunnel junction pattern, and performing a heat treatment process so that boron included in the upper and lower magnetic layers may be absorbed by the boron-absorption layer. The heat treatment process may be undertaken in a gaseous atmosphere including at least one of hydrogen, oxygen, and nitrogen.

Abstract: Provided are a magnetic memory device and a method of forming the same. The magnetic memory device includes a magnetic tunnel junction pattern located on a substrate and including magnetic patterns and a tunnel barrier pattern located between the magnetic patterns, and a first crystallinity conserving pattern located on the magnetic tunnel junction pattern and having a higher crystallization temperature than the magnetic patterns. The first crystallinity conserving pattern is amorphous.

Abstract: A magnetic memory device is provided. The magnetic memory device may include a plurality of word lines extending along a direction crossing a plurality of active regions and at least one source line connected to a plurality of first active regions arranged on a level that is lower than the upper surface of a substrate. A plurality of contact pads may be connected to a plurality of second active regions and a plurality of buried contact plugs may be connected to the plurality of second active regions via the plurality of contact pads. Said buried contact pads may further be arranged in a hexagonal array structure. A plurality of variable resistance structures may be connected to the plurality of second active regions and arranged in a hexagonal array structure.

Abstract: A magnetic memory device is provided. The magnetic memory device may include a plurality of word lines extending along a direction crossing a plurality of active regions and at least one source line connected to a plurality of first active regions arranged on a level that is lower than the upper surface of a substrate. A plurality of contact pads may be connected to a plurality of second active regions and a plurality of buried contact plugs may be connected to the plurality of second active regions via the plurality of contact pads. Said buried contact pads may further be arranged in a hexagonal array structure. A plurality of variable resistance structures may be connected to the plurality of second active regions and arranged in a hexagonal array structure.

Abstract: A magnetic memory device using magnetic resistance is provided. The magnetic memory device may include a magnetic memory layer comprising a plurality of magnetic layers; and a tunnel barrier layer provided between the plurality of magnetic layers; and a stress-generating layer for applying stress to the tunnel barrier layer.