Abstract: A semiconductor memory device includes a cell gate dielectric layer and a cell gate electrode disposed in a gate recess region crossing a cell active portion of a substrate, first and second doped regions disposed in the cell active portion at both sides of the gate recess region, respectively, at least one interlayer insulating layer covering the substrate, a data storage element electrically connected to the second doped region through a contact plug penetrating the at least one interlayer insulating layer, a mold layer covering the data storage element, and a bit line disposed in a cell groove formed in the mold layer. The bit line is in direct contact with a top surface of the data storage element.

Abstract: Methods for manufacturing a data storage device are provided. A method may include forming an interlayer dielectric layer on a substrate, patterning the interlayer dielectric layer in a peripheral region of the substrate to form first trenches, forming first bit lines in the first trenches, patterning the interlayer dielectric layer between the first bit lines in the peripheral region to form second trenches extending along the first trenches after the formation of the first bit lines, and forming second bit lines in the second trenches.

Abstract: A semiconductor memory device includes a first insulating layer covering a substrate, a first contact plug and a second contact plug each penetrating the first insulating layer, a first data storage element disposed on the first contact plug, and a second data storage element disposed on the second contact plug. The first contact plug includes a vertically extending portion and a horizontally extending portion arranged between the vertically extending portion and the first data storage element, and the second contact plug extends substantially vertically from a top surface of the substrate. The first data storage element is laterally spaced apart from the vertically extending portion when viewed in plan view. The first data storage element is disposed on the horizontally extending portion.

Abstract: A magnetic memory device is provided. The magnetic memory device includes a plurality of variable resistance devices connected to a word line, and a plurality of bit lines, each of which provides an electrical pathway between a corresponding one of the variable resistance devices and a read and write circuit. Each of the variable resistance devices includes a free layer and a pinned layer spaced apart from each other and having a tunnel barrier interposed therebetween, an assistant layer spaced apart from the tunnel barrier and having the free layer interposed therebetween, and an exchange coupling layer arranged between the free layer and the assistant layer. The exchange coupling layer has an electric polarization, which results from its ferroelectric property, and having a direction that can be changed by a voltage applied to the corresponding one of the bit lines.

Abstract: Magnetic memory devices are provided. A magnetic memory device includes a Magnetic Tunnel Junction (MTJ) structure on a contact. Moreover, the magnetic memory device includes an insulating structure and an electrode between the MTJ structure and the contact. In some embodiments, a first contact area of the electrode with the MTJ structure is smaller than a second contact area of the insulating structure with the MTJ structure.

Abstract: Provided is a semiconductor device including magnetic tunnel junctions, which are spaced apart from each other on a substrate, and each of which includes a free magnetic pattern, a first pinned magnetic pattern, and a tunnel barrier pattern therebetween. The semiconductor device further includes a separation structure interposed between the magnetic tunnel junctions. The separation structure includes a second pinned magnetic pattern and a first insulating pattern stacked to each other.

Abstract: Memory devices and methods of fabricating the same include a substrate including a cell region and a peripheral circuit region, data storages on the cell region, first bit lines on and coupled to the data storages, first contacts coupled to peripheral transistors on the peripheral circuit region, and second bit lines on and coupled to the first contacts. The second bit lines may each have a lowermost surface lower than a lowermost surface of the data storages.

Abstract: A semiconductor memory device includes a first insulating layer covering a substrate, a first contact plug and a second contact plug each penetrating the first insulating layer, a first data storage element disposed on the first contact plug, and a second data storage element disposed on the second contact plug. The first contact plug includes a vertically extending portion and a horizontally extending portion arranged between the vertically extending portion and the first data storage element, and the second contact plug extends substantially vertically from a top surface of the substrate. The first data storage element is laterally spaced apart from the vertically extending portion when viewed in plan view. The first data storage element is disposed on the horizontally extending portion.

Abstract: A magnetic memory device is provided. The magnetic memory device includes a plurality of variable resistance devices connected to a word line, and a plurality of bit lines, each of which provides an electrical pathway between a corresponding one of the variable resistance devices and a read and write circuit. Each of the variable resistance devices includes a free layer and a pinned layer spaced apart from each other and having a tunnel barrier interposed therebetween, an assistant layer spaced apart from the tunnel barrier and having the free layer interposed therebetween, and an exchange coupling layer arranged between the free layer and the assistant layer. The exchange coupling layer has an electric polarization, which results from its ferroelectric property, and having a direction that can be changed by a voltage applied to the corresponding one of the bit lines.

Abstract: Memory devices and methods of fabricating the same include a substrate including a cell region and a peripheral circuit region, data storages on the cell region, first bit lines on and coupled to the data storages, first contacts coupled to peripheral transistors on the peripheral circuit region, and second bit lines on and coupled to the first contacts. The second bit lines may each have a lowermost surface lower than a lowermost surface of the data storages.

Abstract: Methods for manufacturing a data storage device are provided. A method may include forming an interlayer dielectric layer on a substrate, patterning the interlayer dielectric layer in a peripheral region of the substrate to form first trenches, forming first bit lines in the first trenches, patterning the interlayer dielectric layer between the first bit lines in the peripheral region to form second trenches extending along the first trenches after the formation of the first bit lines, and forming second bit lines in the second trenches.

Abstract: Memory devices and methods of fabricating the same include a substrate including a cell region and a peripheral circuit region, data storages on the cell region, first bit lines on and coupled to the data storages, first contacts coupled to peripheral transistors on the peripheral circuit region, and second bit lines on and coupled to the first contacts. The second bit lines may each have a lowermost surface lower than a lowermost surface of the data storages.

Abstract: A semiconductor memory device includes a cell gate dielectric layer and a cell gate electrode disposed in a gate recess region crossing a cell active portion of a substrate, first and second doped regions disposed in the cell active portion at both sides of the gate recess region, respectively, at least one interlayer insulating layer covering the substrate, a data storage element electrically connected to the second doped region through a contact plug penetrating the at least one interlayer insulating layer, a mold layer covering the data storage element, and a bit line disposed in a cell groove formed in the mold layer. The bit line is in direct contact with a top surface of the data storage element.

Abstract: Memory devices and methods of fabricating the same include a substrate including a cell region and a peripheral circuit region, data storages on the cell region, first bit lines on and coupled to the data storages, first contacts coupled to peripheral transistors on the peripheral circuit region, and second bit lines on and coupled to the first contacts. The second bit lines may each have a lowermost surface lower than a lowermost surface of the data storages.

Abstract: In a method of making a dual work function gate electrode of a CMOS semiconductor structure, the improvement comprising formation of the dual work function gate electrode so that there is no boron penetration in the channel region and no boron depletion near the gate oxide, comprising: a) forming a gate oxide layer over a channel of a nMOS site and over a channel of a pMOS site; b) forming an undoped polysilicon layer over the gate oxide layer; c) masking the pMOS site, forming an a-Si layer over the nMOS site using a first heavy ion implantation, and implanting arsenic solely into the a-Si layer; d) masking the nMOS site formed by step c), forming an a-Si layer over the pMOS site using a second heavy ion implantation, and implanting boron solely into the a-Si regions; e) laser annealing the nMOS and pMOS sites for a short time and at an energy level sufficient to melt at least a portion of the a-Si but insufficient to melt the polysilicon; and f) affecting cooling after laser annealing to convert a-Si into p

Abstract: A process as shown in FIGS. 1A through 1I, or FIGS. 2A through 2I for providing first areas of gate oxide (30, 30A, 30B) on a substrate (10) having a first thickness and second adjacent areas (32, 32A, 32B) of gate oxide having a lesser thickness without the use of a N2 implantation process.

Abstract: In a method of making a dual work function gate electrode of a CMOS semiconductor structure, the improvement comprising formation of the dual work function gate electrode so that there is no boron penetration in the channel region and no boron depletion near the gate oxide, comprising:

Abstract: In a method of forming a microelectronic structure of a Pt/BSTO/Pt capacitor stack for use in a DRAM device, the improvement comprising substantially eliminating or preventing oxygen out-diffusion from the BSTO material layer, comprising: a) preparing a bottom Pt electrode formation; b) subjecting the bottom Pt electrode formation to an oxygen plasma treatment to form an oxygen enriched Pt layer on the bottom Pt electrode; c) depositing a BSTO layer on said oxygen enriched Pt layer; d) depositing an upper Pt electrode layer on the BSTO layer; e) subjecting the upper Pt electrode layer to an oxygen plasma treatment to form an oxygen incorporated Pt layer; and f) depositing a Pt layer on the oxygen incorporated Pt layer upper Pt elect.