Abstract: A semiconductor memory device includes a substrate including a device isolation film defining active regions; and cell gate structures in trenches, including first areas and second areas, the cell gate structures extending to intersect the active regions, each of the cell gate structures includes a cell gate insulating layer, extending along inner sidewalls of the trenches, a first gate dielectric film, on sidewalls of the cell gate insulating layer, in a first area of the trench, a second gate dielectric film, on the sidewalls of the cell gate insulating layer, in a second area of the trench, and a cell gate electrode structure, including a first gate electrode layer on sidewalls of the first gate dielectric film and a second gate electrode layer on sidewalls of the second gate dielectric film in the second area.

Abstract: A semiconductor device is disclosed. The semiconductor memory device comprises a substrate including an active region, an element isolation film disposed in the substrate and that defines the active region, a recess which is disposed in the active region and extends in a first direction, and a gate structure extending in a second direction, on the active region, wherein the gate structure includes a gate insulating film, a gate stack pattern, and a gate capping pattern which are sequentially stacked, wherein the gate insulating film extends along an upper face of the active region, and a part of the gate insulating film fills the recess, and wherein a height from a lower face of the substrate to a bottom face of the element isolation film is less than a height from the lower face of the substrate to a bottom face of the recess.

Abstract: A semiconductor memory device comprises a substrate including a first source/drain region and a second source/drain region, a trench between the first source/drain region and the second source/drain region and formed in the substrate, a cell gate insulating layer on sidewalls and a bottom surface of the trench, a cell gate electrode on the cell gate insulating layer, a work function control pattern on the cell gate electrode, including N-type impurities and a cell gate capping pattern on the work function control pattern. The work function control pattern includes a semiconductor material. The work function control pattern includes a first region and a second region between the first region and the cell gate electrode. A concentration of the N-type impurities in the first region is greater than a concentration of the N-type impurities in the second region.

Abstract: A semiconductor device may include a substrate including trenches and contact recesses having a curved surface profile, conductive patterns in the trenches, buried contacts including first portions filling the contact recesses and second portions on the first portions, and spacer structures including first and second spacers. The second portions may have a pillar shape and a smaller width than top surfaces of the first portions. The buried contacts may be spaced apart from the conductive patterns by the spacer structures. The first spacers may be on the first portions of the buried contacts at outermost parts of the spacer structures. The first spacers may extend along the second portions of the buried contacts and contact the buried contacts. The second spacers may extend along the side surfaces of the conductive patterns and the trenches. The second spacers may contact the conductive patterns. The first spacers may include silicon oxide.

Abstract: Disclosed are a semiconductor device and a method of fabricating the same. The semiconductor device may include a substrate having a groove therein extending in a first direction, a gate insulating layer in the groove, a first conductive pattern in the groove and on the gate insulating layer, and a word line capping pattern in the groove and on the first conductive pattern. The first conductive pattern may include a first material and may include a first conductive portion adjacent to the word line capping pattern and a second conductive portion adjacent to a bottom end of the groove. A largest dimension of a grain of the first material of the first conductive portion may be equal to or larger than that of the first material of the second conductive portion.

Abstract: A semiconductor device may include a substrate including trenches and contact recesses having a curved surface profile, conductive patterns in the trenches, buried contacts including first portions filling the contact recesses and second portions on the first portions, and spacer structures including first and second spacers. The second portions may have a pillar shape and a smaller width than top surfaces of the first portions. The buried contacts may be spaced apart from the conductive patterns by the spacer structures. The first spacers may be on the first portions of the buried contacts at outermost parts of the spacer structures. The first spacers may extend along the second portions of the buried contacts and contact the buried contacts. The second spacers may extend along the side surfaces of the conductive patterns and the trenches. The second spacers may contact the conductive patterns. The first spacers may include silicon oxide.

Abstract: A memory device includes: a substrate including a first active region and a second active region spaced apart from each other; a device isolation film on the substrate, the device isolation film defining the first active region and the second active region; and a buried word line structure passing a low dielectric region between the first active region and the second active region, wherein the buried word line structure includes a gate electrode in a gate trench and a gate insulating layer between a portion of the gate electrode outside the low dielectric region and the gate trench, and wherein an air gap is disposed between a portion of the gate electrode within the low dielectric region and the gate trench.

Abstract: A semiconductor device including a semiconductor substrate including a trench, the semiconductor substrate having a crystal structure; and an insulating layer covering an inner sidewall of the trench, wherein the inner sidewall of the trench has at least one plane included in a {320} family of planes of the crystal structure or at least one plane similar to the {320} family of planes.

Abstract: A semiconductor device includes a substrate, device isolation film defining an active region of the substrate in which a gate trench extends, a gate insulating film disposed along sides and a bottom of the gate trench, a gate electrode disposed on the gate insulating film in the gate trench and having a first portion, a second portion on the first portion, and a third portion on the second portion, a first barrier film pattern interposed between the first portion of the gate electrode and the gate insulating film, a second barrier film pattern interposed between the second portion of the gate electrode and the gate insulating film, and a third barrier film pattern interposed between the third portion of the gate electrode and the gate insulating film. The work function of the first barrier film pattern is greater than the work function of the second barrier film pattern and less than the work function of the third barrier film pattern.

Abstract: A semiconductor device includes a substrate, device isolation film defining an active region of the substrate in which a gate trench extends, a gate insulating film disposed along sides and a bottom of the gate trench, a gate electrode disposed on the gate insulating film in the gate trench and having a first portion, a second portion on the first portion, and a third portion on the second portion, a first barrier film pattern interposed between the first portion of the gate electrode and the gate insulating film, a second barrier film pattern interposed between the second portion of the gate electrode and the gate insulating film, and a third barrier film pattern interposed between the third portion of the gate electrode and the gate insulating film. The work function of the first barrier film pattern is greater than the work function of the second barrier film pattern and less than the work function of the third barrier film pattern.

Abstract: An integrated circuit device may include a gate dielectric layer on an inner surface of a gate trench of a substrate, a gate structure filling a portion of the gate trench on the gate dielectric layer, and an insulating, capping pattern on an upper surface of the gate structure in the gate trench. The gate structure may include a lower gate line having a first work function, an upper gate line having a second work function lower than the first work function, a first blocking layer between the lower gate line and the upper gate line, and a second blocking layer between the upper gate line and the insulating capping pattern.

Abstract: An integrated circuit device may include a gate dielectric layer on an inner surface of a gate trench of a substrate, a gate structure filling a portion of the gate trench on the gate dielectric layer, and an insulating, capping pattern on an upper surface of the gate structure in the gate trench. The gate structure may include a lower gate line having a first work function, an upper gate line having a second work function lower than the first work function, a first blocking layer between the lower gate line and the upper gate line, and a second blocking layer between the upper gate line and the insulating capping pattern.

Abstract: A semiconductor device including a semiconductor substrate including a trench, the semiconductor substrate having a crystal structure; and an insulating layer covering an inner sidewall of the trench, wherein the inner sidewall of the trench has at least one plane included in a {320} family of planes of the crystal structure or at least one plane similar to the {320} family of planes.

Abstract: A four transistor layout can include an isolation region that defines an active region, the active region extending along first and second different directions. A common source region of the four transistors extends from a center of the active region along both the first and second directions to define four quadrants of the active region that are outside the common source region. Four drain regions are provided, a respective one of which is in a respective one of the four quadrants and spaced apart from the common source region. Finally, four gate electrodes are provided, a respective one of which is in a respective one of the four quadrants between the common source region and a respective one of the four drain regions. A respective gate electrode includes a vertex and first and second extending portions, the first extending portions extending from the vertex along the first direction and the second extending portions extending from the vertex along the second direction.

Abstract: A four transistor layout can include an isolation region that defines an active region, the active region extending along first and second different directions. A common source region of the four transistors extends from a center of the active region along both the first and second directions to define four quadrants of the active region that are outside the common source region. Four drain regions are provided, a respective one of which is in a respective one of the four quadrants and spaced apart from the common source region. Finally, four gate electrodes are provided, a respective one of which is in a respective one of the four quadrants between the common source region and a respective one of the four drain regions. A respective gate electrode includes a vertex and first and second extending portions, the first extending portions extending from the vertex along the first direction and the second extending portions extending from the vertex along the second direction.

Abstract: A semiconductor memory device includes a bit line connected to a memory cell; an input/output line configured to input a data signal to the memory cell during a writing operation and to output a data signal stored in the memory cell during a reading operation; and a column select transistor including a first source/drain connected to the bit line and a second source/drain connected to the input/output line, wherein a resistance of the first source/drain is smaller than a resistance of the second source/drain.

Abstract: A four transistor layout can include an isolation region that defines an active region, the active region extending along first and second different directions. A common source region of the four transistors extends from a center of the active region along both the first and second directions to define four quadrants of the active region that are outside the common source region. Four drain regions are provided, a respective one of which is in a respective one of the four quadrants and spaced apart from the common source region. Finally, four gate electrodes are provided, a respective one of which is in a respective one of the four quadrants between the common source region and a respective one of the four drain regions. A respective gate electrode includes a vertex and first and second extending portions, the first extending portions extending from the vertex along the first direction and the second extending portions extending from the vertex along the second direction.

Abstract: A four transistor layout can include an isolation region that defines an active region, the active region extending along first and second different directions. A common source region of the four transistors extends from a center of the active region along both the first and second directions to define four quadrants of the active region that are outside the common source region. Four drain regions are provided, a respective one of which is in a respective one of the four quadrants and spaced apart from the common source region. Finally, four gate electrodes are provided, a respective one of which is in a respective one of the four quadrants between the common source region and a respective one of the four drain regions. A respective gate electrode includes a vertex and first and second extending portions, the first extending portions extending from the vertex along the first direction and the second extending portions extending from the vertex along the second direction.

Abstract: A semiconductor device is disclosed. The semiconductor device includes a semiconductor substrate, a first node impurity region, a second node impurity region, a third node impurity region, and an insulating layer. The first through third node impurity regions are disposed in the semiconductor substrate. Each of the first through third node impurity regions has a longitudinal length, a transverse length and a thickness respectively corresponding to first through third directions, which are perpendicular with respect to each other. The first node impurity region is parallel to the second and third node impurity regions, which are disposed in the substantially same line. The insulating layer is located between the first through third node impurity regions in the semiconductor substrate.

Abstract: A semiconductor device includes a substrate including a memory cell region and a peripheral region and a field pattern including an insulating region disposed on a nitride liner in a trench in the substrate adjacent an active region. The field pattern and the active region extend in parallel through the cell and peripheral regions. The device also includes a transistor in the peripheral region including a source/drain region in the active region. The device further includes an insertion pattern including an elongate conductive region disposed in the substrate and extending along a boundary between the field pattern and the active region in the peripheral region. Fabrication methods are also described.