Abstract: A semiconductor device and method for fabricating the same are provided. The semiconductor device includes a substrate including a cell region, a core region, and a boundary region between the cell region and the core region, a boundary element isolation layer in the boundary region of the substrate to separate the cell region from the core region, a high-k dielectric layer on at least a part of the boundary element isolation layer and the core region of the substrate, a first work function metal pattern comprising a first extension overlapping the boundary element isolation layer on the high-k dielectric layer, and a second work function metal pattern comprising a second extension overlapping the boundary element isolation layer on the first work function metal pattern, wherein a first length of the first extension is different from a second length of the second extension.

Abstract: A semiconductor device including a substrate with a first trench, a first insulation liner on inner flanks of the first trench, and a second insulation liner on inner flanks of a first sub trench, the first insulation trench defined by the first insulation liner in the first trench, a top level of the second insulation liner that adjoins the inner flanks of the first sub trench in a direction perpendicular to a top surface of the substrate being different from the top surface of the substrate outside the first trench, may be provided.

Abstract: A method for fabricating a semiconductor device includes forming a device isolation film on a substrate between first and second regions, forming first and second sealing films, such that an etch selectivity of the second sealing film is smaller than that of the first sealing film, patterning the first and second sealing films to expose the second region and a portion of the device isolation film, such that an undercut is defined under a lower surface of the second sealing film, forming a filling film filling the undercut, a thickness of the filling film being thicker on a side surface of the second sealing film than on an upper surface thereof, removing a portion of the filling film to form a filling spacer in the undercut, forming a high-k dielectric film and a metal film on the filling spacer, and patterning the high-k dielectric film and the metal film.

Abstract: A semiconductor device includes a substrate including a cell active region and a peripheral active region, a direct contact arranged on a cell insulating pattern formed on the substrate and connected to the cell active region, a bit line structure including a thin conductive pattern, contacting a top surface of the direct contact and extending in one direction, and a peripheral gate structure in the peripheral active region. The peripheral gate structure include a stacked structure of a peripheral gate insulating pattern and a peripheral gate conductive pattern, the thin conductive pattern includes a first material and the peripheral gate conductive pattern include the first material, and a level of an upper surface of the thin conductive pattern is lower than a level of an upper surface of the peripheral gate conductive pattern.

Abstract: A semiconductor device includes a substrate, first, second and third structures disposed on the substrate and spaced apart from one another in a first direction, wherein each of the first, second and third structures includes lower electrodes, and a supporter pattern supporting the first, second and third structures and including a first region and a second region, wherein the first region exposes first parts of sidewalls of the first, second and third structures, and the second region surrounds second parts of the sidewalls of the first, second and third structures. A first length of a sidewall of the supporter pattern between the first and second structures is greater than a first distance between the first and second structures. A second length of a sidewall of the supporter pattern between the second and third structures is greater than a second distance between the second and third structures.

Abstract: A semiconductor device includes a substrate including a cell array region including a cell active region. An insulating pattern is on the substrate. The insulating pattern includes a direct contact hole which exposes the cell active region and extends into the cell active region. A direct contact conductive pattern is in the direct contact hole and is connected to the cell active region. A bit line is on the insulating pattern. The bit line is connected to the direct contact conductive pattern and extends in a direction orthogonal to an upper surface of the insulating pattern. The insulating pattern includes a first insulating pattern including a non-metal-based dielectric material and a second insulating pattern on the first insulating pattern. The second insulating pattern includes a metal-based dielectric material having a higher dielectric constant than a dielectric constant of the first insulating pattern.

Abstract: A method of forming a pattern includes forming a first level pattern layer on a feature layer on a substrate. The first level pattern layer includes a plurality of first line patterns and a plurality of first space burying patterns. The first line patterns extend parallel to one another in a first direction and the first space burying patterns extend parallel to one another in the first direction with first line patterns alternately disposed with first space burying patterns A portion of the plurality of first space burying patterns may be removed to form a second direction pattern space extending intermittently or continuously in the first level pattern layer. A second burying layer filling the second direction pattern space may be formed to form a network structure pattern. The feature layer may be etched with the network structure pattern as an etch mask to form a pattern of holes.

Abstract: The semiconductor device including: a semiconductor layer extending in a first direction, the semiconductor layer including a pair of source/drain regions and a channel region, a gate extending on the semiconductor layer to cover the channel region, and a gate dielectric layer interposed between the channel region and the gate, a corner insulating spacer having a first surface and a second surface, the first surface extending in the second direction along a side wall of the gate, the first surface covering from a side portion of the gate dielectric layer to at least a portion of the side wall of the gate, and the second surface covering a portion of the semiconductor layer, and an outer portion insulating spacer covering the side wall of the gate above the corner insulating spacer, the outer portion insulating spacer having a smaller dielectric constant than the corner insulating spacer, may be provided.

Abstract: A semiconductor device includes a substrate including spaced-apart active regions, and device isolating regions isolating the active regions from each other, and a pillar array pattern including a plurality of pillar patterns overlapping the active regions, the plurality of pillar patterns being spaced apart from each other at an equal distance in a first direction and in a second direction intersecting the first direction, wherein the plurality of pillar patterns include first pillar patterns and second pillar patterns disposed alternatingly in the first direction and in the second direction, a shape of a horizontal cross section of the first pillar patterns being different from a shape of a horizontal cross section of the second pillar patterns.

Abstract: A method of forming a pattern includes forming a first level pattern layer on a feature layer on a substrate. The first level pattern layer includes a plurality of first line patterns and a plurality of first space burying patterns. The first line patterns extend parallel to one another in a first direction and the first space burying patterns extend parallel to one another in the first direction with first line patterns alternately disposed with first space burying patterns A portion of the plurality of first space burying patterns may be removed to form a second direction pattern space extending intermittently or continuously in the first level pattern layer. A second burying layer filling the second direction pattern space may be formed to form a network structure pattern. The feature layer may be etched with the network structure pattern as an etch mask to form a pattern of holes.

Abstract: A semiconductor device includes: a first interconnection line and a second interconnection line which extend apart from each other on a first plane at a first level on a substrate; a bypass interconnection line that extends on a second plane at a second level on the substrate; and a plurality of contact plugs for connecting the bypass interconnection line to the first interconnection line and the second interconnection line. A method includes forming a bypass interconnection line spaced apart from a substrate and forming on a same plane a plurality of interconnection lines connected to the bypass interconnection line via a plurality of contact plugs.

Abstract: A semiconductor device includes conductive lines spaced from a substrate, and an insulating spacer structure between the conductive lines and defining a contact hole. The insulating spacer structure is adjacent a side wall of at least one of the conductive lines. The device also includes an insulating pattern on the conductive lines and insulating spacer structure, and another insulating pattern defining a landing pad hole connected to the contact hole. A contact plug is formed in the contact hole and connects to the active area. A landing pad is formed in the landing pad hole and connects to the contact plug. The landing pad vertically overlaps one of the pair of conductive line structures.

Abstract: A semiconductor device includes: a first interconnection line and a second interconnection line which extend apart from each other on a first plane at a first level on a substrate; a bypass interconnection line that extends on a second plane at a second level on the substrate; and a plurality of contact plugs for connecting the bypass interconnection line to the first interconnection line and the second interconnection line. A method includes forming a bypass interconnection line spaced apart from a substrate and forming on a same plane a plurality of interconnection lines connected to the bypass interconnection line via a plurality of contact plugs.

Abstract: An MRAM device may include semiconductor structures, a common source region, a drain region, a channel region, gate structures, word line structures, MTJ structures, and bit line structures arranged on a substrate. Each of the semiconductor structures may include a first semiconductor pattern having a substantially linear shape extending in a first direction that is substantially parallel to a top surface of the substrate, and a plurality of second patterns that each extend in a third direction substantially perpendicular to the top surface of the substrate. A common source region and drain region may be formed in each of the semiconductor structures to be spaced apart from each other in the third direction, and the channel region may be arranged between the common source region and the drain region. Gate structures may be formed between adjacent second semiconductor patterns in the second direction. Word line structures may electrically connect gate structures arranged in the first direction to each other.

Abstract: Provided is a memory device. The memory device includes a substrate including a cell area and a peripheral area; gate line stacks and bit line stacks configured to vertically cross in the cell area; buried contacts disposed in areas, which are simultaneously shared by neighboring gate line stacks and neighboring bit line stacks; expanded landing pads including expanded portions connected to the buried contacts and expanded over adjacent bit line stacks, and disposed in a row; landing pads spaced apart from the expanded landing pads as a column, connected to the buried contacts, and having horizontal widths smaller than those of the expanded landing pads; and first storage nodes connected to the expanded portions of the expanded landing pads, and second storage nodes connected to the landing pads.

Abstract: Semiconductor devices include a substrate having a target connection region; a conductive line having a first side wall spaced apart from the substrate by at least an insulating layer, and a conductive plug structure electrically connecting the conductive line to the target connection region, wherein the conductive plug includes a first conductive plug having a first side wall, a bottom surface contacting the target connection region of the substrate, and a second side wall facing the first side wall of the conductive line, and a second conductive plug between the conductive line and the first conductive plug. The second conductive plug contacts both the first side wall of the conductive line and the second side wall of the first conductive plug.

Abstract: A semiconductor device includes conductive lines spaced from a substrate, and an insulating spacer structure between the conductive lines and defining a contact hole. The insulating spacer structure is adjacent a side wall of at least one of the conductive lines. The device also includes an insulating pattern on the conductive lines and insulating spacer structure, and another insulating pattern defining a landing pad hole connected to the contact hole. A contact plug is formed in the contact hole and connects to the active area. A landing pad is formed in the landing pad hole and connects to the contact plug. The landing pad vertically overlaps one of the pair of conductive line structures.

Abstract: An electronic device may include a substrate, and a plurality of spaced apart pads on the substrate. Each of the pads may includes first, second, third, and fourth sides, the first and third sides may be opposite sides that are substantially straight, and the second and fourth sides may be opposite sides that are curved. Related methods, devices, and structures are also discussed.

Abstract: The semiconductor device including: a semiconductor layer extending in a first direction, the semiconductor layer including a pair of source/drain regions and a channel region, a gate extending on the semiconductor layer to cover the channel region, and a gate dielectric layer interposed between the channel region and the gate, a corner insulating spacer having a first surface and a second surface, the first surface extending in the second direction along a side wall of the gate, the first surface covering from a side portion of the gate dielectric layer to at least a portion of the side wall of the gate, and the second surface covering a portion of the semiconductor layer, and an outer portion insulating spacer covering the side wall of the gate above the corner insulating spacer, the outer portion insulating spacer having a smaller dielectric constant than the corner insulating spacer, may be provided.

Abstract: A semiconductor device includes conductive lines spaced from a substrate, and an insulating spacer structure between the conductive lines and defining a contact hole. The insulating spacer structure is adjacent a side wall of at least one of the conductive lines. The device also includes an insulating pattern on the conductive lines and insulating spacer structure, and another insulating pattern defining a landing pad hole connected to the contact hole. A contact plug is formed in the contact hole and connects to the active area. A landing pad is formed in the landing pad hole and connects to the contact plug. The landing pad vertically overlaps one of the pair of conductive line structures.