Abstract: A semiconductor device includes a cell semiconductor pattern disposed on a semiconductor substrate. A semiconductor dummy pattern is disposed on the semiconductor substrate. The semiconductor dummy pattern is co-planar with the cell semiconductor pattern. A first circuit is disposed between the semiconductor substrate and the cell semiconductor pattern. A first interconnection structure is disposed between the semiconductor substrate and the cell semiconductor pattern. A first dummy structure is disposed between the semiconductor substrate and the cell semiconductor pattern. Part of the first dummy structure is co-planar with part of the first interconnection structure. A second dummy structure not overlapping the cell semiconductor pattern is disposed on the semiconductor substrate. Part of the second dummy structure is co-planar with part of the first interconnection structure.

Abstract: A semiconductor device is provided including a resistor structure on a semiconductor substrate. The resistor structure includes pad portions and a resistor body connecting the pad portions. The pad portions each have a width greater than a width of the resistor body. The pad portions each include a pad pattern and a liner pattern covering a sidewall and a lower surface of the pad pattern. The resistor body extends laterally from the liner pattern. The pad pattern includes a different material from the resistor body and the liner pattern.

Abstract: Semiconductor memory devices are provided. A semiconductor memory device includes a memory cell region and an insulator on a portion of the memory cell region. The semiconductor memory device includes a stress relief material that is in the insulator and is between the memory cell region and another region of the semiconductor memory device.

Abstract: A three-dimensional (3D) semiconductor device includes a substrate having a cell array region and a peripheral circuit region. A cell array structure is in the cell array region and includes a 3D memory cell array. A peripheral logic structure is in the peripheral circuit region and includes a peripheral circuit transistor. A cell insulating layer insulates the cell array structure. A peripheral insulating layer is insulated from the peripheral logic structure and the cell array region and has a porous layer.

Abstract: A vertical memory device includes a gate structure on a peripheral circuit region of a substrate, the substrate including a cell region and the peripheral circuit region, and the gate structure including a first gate electrode, second, third, and fourth gate electrodes sequentially disposed at a plurality of levels, respectively, on the cell region of the substrate in a vertical direction substantially perpendicular to an upper surface of the substrate, a first epitaxial layer extending through the second gate electrode on the cell region of the substrate, a channel extending through the third and fourth gate electrodes in the vertical direction on the first epitaxial layer, and a second epitaxial layer on a portion of the peripheral circuit region of the substrate adjacent the gate structure.

Abstract: Provided are a semiconductor device, a method of manufacturing the semiconductor device, and an electronic system adopting the same. The semiconductor device includes a semiconductor pattern, which is disposed on a semiconductor substrate and has an opening. The semiconductor pattern includes a first impurity region having a first conductivity type and a second impurity region having a second conductivity type different from the first conductivity type. A peripheral transistor is disposed between the semiconductor substrate and the semiconductor pattern. A first peripheral interconnection structure is disposed between the semiconductor substrate and the semiconductor pattern. The first peripheral interconnection structure is electrically connected to the peripheral transistor. Cell gate conductive patterns are disposed on the semiconductor pattern. Cell vertical structures are disposed to pass through the cell gate conductive patterns and to be connected to the semiconductor pattern.

Abstract: Semiconductor devices are provided. A semiconductor device includes a peripheral circuit region and a first memory region that are side by side on a substrate. Moreover, the semiconductor device includes a second memory region that is on the peripheral circuit region and the first memory region. Related methods of programming semiconductor devices are also provided.

Abstract: The inventive concepts provide methods for fabricating a semiconductor device and semiconductor devices fabricated by the same. According to the method, conductive lines having a fine pitch smaller than the minimum pitch realized by an exposure process may be formed using two or three photolithography processes and two spacer formation processes. In addition, node separation regions of the conductive lines may be easily formed without a misalignment problem.

Abstract: A semiconductor device includes a gate stack including gate electrodes stacked vertically on a substrate. Channel holes penetrate through the gate stack to extend vertically to the substrate. Each of the channel holes includes a channel region. First channel pads are each disposed at an end of a respective channel hole opposite the substrate. Each of the first channel pads includes at least one first conductivity-type impurity. Second channel pads are each disposed at an end of a respective channel hole opposite the substrate. Each of the second channel pads includes at least one second conductivity-type impurity.

Abstract: A vertical memory device includes a channel, a dummy channel, a plurality of gate electrodes, and a support pattern. The channel extends in a first direction perpendicular to an upper surface of a substrate. The dummy channel extends from the upper surface of the substrate in the first direction. The plurality of gate electrodes are formed at a plurality of levels, respectively, spaced apart from each other in the first direction on the substrate. Each of the gate electrodes surrounds outer sidewalls of the channel and the dummy channel. The support pattern is between the upper surface of the substrate and a first gate electrode among the gate electrodes. The first gate electrode is at a lowermost one of the levels. The channel and the dummy channel contact each other between the upper surface of the substrate and the first gate electrode.

Abstract: Provided are a semiconductor device, a method of manufacturing the semiconductor device, and an electronic system adopting the same. The semiconductor device includes a semiconductor pattern, which is disposed on a semiconductor substrate and has an opening. The semiconductor pattern includes a first impurity region having a first conductivity type and a second impurity region having a second conductivity type different from the first conductivity type. A peripheral transistor is disposed between the semiconductor substrate and the semiconductor pattern. A first peripheral interconnection structure is disposed between the semiconductor substrate and the semiconductor pattern. The first peripheral interconnection structure is electrically connected to the peripheral transistor. Cell gate conductive patterns are disposed on the semiconductor pattern. Cell vertical structures are disposed to pass through the cell gate conductive patterns and to be connected to the semiconductor pattern.

Abstract: A semiconductor device may include a cell gate conductive pattern in a cell array area that extends to a step area, a cell vertical structure in the cell array area that extends through the cell gate conductive pattern, a cell gate contact structure on the cell gate conductive pattern in the step area, a cell gate contact region in the cell gate conductive pattern and aligned with the cell gate contact structure, a first peripheral contact structure spaced apart from the cell gate conductive pattern, a second peripheral contact structure spaced apart from the first peripheral contact structure, a first peripheral contact region under the first peripheral contact structure, and a second peripheral contact region under the second peripheral contact structure. The cell gate contact region may include a first element and a remainder of the cell gate conductive pattern may not substantially include the first element.

Abstract: A vertical memory device includes a channel, a dummy channel, a plurality of gate electrodes, and a support pattern. The channel extends in a first direction perpendicular to an upper surface of a substrate. The dummy channel extends from the upper surface of the substrate in the first direction. The plurality of gate electrodes are formed at a plurality of levels, respectively, spaced apart from each other in the first direction on the substrate. Each of the gate electrodes surrounds outer sidewalls of the channel and the dummy channel. The support pattern is between the upper surface of the substrate and a first gate electrode among the gate electrodes. The first gate electrode is at a lowermost one of the levels. The channel and the dummy channel contact each other between the upper surface of the substrate and the first gate electrode.

Abstract: The inventive concepts provide methods for fabricating a semiconductor device and semiconductor devices fabricated by the same. According to the method, conductive lines having a fine pitch smaller than the minimum pitch realized by an exposure process may be formed using two or three photolithography processes and two spacer formation processes. In addition, node separation regions of the conductive lines may be easily formed without a misalignment problem.

Abstract: Semiconductor devices and methods of manufacturing the semiconductor devices are provided. The semiconductor devices may include a semiconductor pattern including an opening on a semiconductor substrate. A peripheral transistor and a peripheral interconnection structure may be disposed between the semiconductor substrate and the semiconductor pattern. The peripheral interconnection structure may be electrically connected to the peripheral transistor. Cell gate conductive patterns may be disposed on the semiconductor pattern. The cell vertical structures may extend through the cell gate conductive patterns and may be connected to the semiconductor pattern. Cell bit line contact plugs may be disposed on the cell vertical structures. A bit line may be disposed on the cell bit line contact plugs. A peripheral bit line contact structure may be disposed between the bit line and the peripheral interconnection structure. The peripheral bit line contact structure may extend through the opening of the semiconductor.

Abstract: A semiconductor device may include a cell gate conductive pattern in a cell array area that extends to a step area, a cell vertical structure in the cell array area that extends through the cell gate conductive pattern, a cell gate contact structure on the cell gate conductive pattern in the step area, a cell gate contact region in the cell gate conductive pattern and aligned with the cell gate contact structure, a first peripheral contact structure spaced apart from the cell gate conductive pattern, a second peripheral contact structure spaced apart from the first peripheral contact structure, a first peripheral contact region under the first peripheral contact structure, and a second peripheral contact region under the second peripheral contact structure. The cell gate contact region may include a first element and a remainder of the cell gate conductive pattern may not substantially include the first element.

Abstract: A semiconductor device includes a substrate, a plurality of memory cell arrays, and an air gap structure. The substrate includes a cell region, a peripheral circuit region, and a boundary region. The boundary region is between the cell region and the peripheral circuit region. The plurality of memory cell arrays are on the cell region. The air gap structure includes a trench formed in the boundary region of the substrate. The air gap structure defines an air gap.

Abstract: An operating method of a nonvolatile memory device is provided which sequentially performs a plurality of erase loops to erase at least one of a plurality of memory blocks. The operating method comprises performing at least one of the plurality of erase loops; performing a post-program operation on the at least one memory block after the at least one erase loop is executed; and performing remaining erase loops of the plurality of erase loops. The post-program operation is not performed when each of the remaining erase loops is executed.

Abstract: A vertical memory device includes a channel, a dummy channel, a plurality of gate electrodes, and a support pattern. The channel extends in a first direction perpendicular to an upper surface of a substrate. The dummy channel extends from the upper surface of the substrate in the first direction. The plurality of gate electrodes are formed at a plurality of levels, respectively, spaced apart from each other in the first direction on the substrate. Each of the gate electrodes surrounds outer sidewalls of the channel and the dummy channel. The support pattern is between the upper surface of the substrate and a first gate electrode among the gate electrodes. The first gate electrode is at a lowermost one of the levels. The channel and the dummy channel contact each other between the upper surface of the substrate and the first gate electrode.

Abstract: A semiconductor device includes a plurality of line patterns including at least two continuous line repetition units having, as one of the line repetition unit, four line patterns continuously arranged in a first direction and having variable widths based on location. To form the plurality of line patterns including the at least two continuous line repetition units, a plurality of reference patterns are formed repeatedly at a uniform reference pitch on a feature layer. A plurality of first spacers covering both side walls of each of the plurality of reference patterns are formed. A plurality of second spacers covering both side walls of each of the plurality of first spacers are formed by removing the plurality of reference patterns. The feature layer is etched using the plurality of second spacers as an etch mask by removing the plurality of first spacers.