Abstract: In an integrated circuit device and method of manufacturing the same, a resistor pattern is positioned on a device isolation layer of a substrate. The resistor pattern includes a resistor body positioned in a recess portion of the device isolation layer and a connector making contact with the resistor body and positioned on the device isolation layer around the recess portion. The connector has a metal silicide pattern having electric resistance lower than that of the resistor body at an upper portion. A gate pattern is positioned on the active region of the substrate and includes the metal silicide pattern at an upper portion. A resistor interconnection is provided to make contact with the connector of the resistor pattern. A contact resistance between the connector and the resistor interconnection is reduced.

Abstract: A method of forming an active region structure includes preparing a semiconductor substrate having a cell array region and a peripheral circuit region, forming upper cell mask patterns having a line shape in the cell array region, forming first and second peripheral mask patterns in the peripheral circuit region, the first and second peripheral mask patterns being stacked in sequence and covering the peripheral circuit region, and upper surfaces of the upper cell mask patterns forming a step difference with an upper surface of the second peripheral mask pattern, forming spacers on sidewalls of the upper cell mask patterns to expose lower portions of the upper cell mask patterns and the second peripheral mask pattern, and removing the lower portions of the upper cell mask patterns using the spacers and the first and second peripheral mask patterns as an etch mask.

Abstract: A flash memory device, including a cell array region where a plurality of memory cells are connected in series to a single cell string, the cell array region including a pocket p-well configured to accommodate the plurality of memory cells and an n-well configured to surround the pocket p-well, a first peripheral region where low-voltage (LV) and high-voltage (HV) switches are connected to the memory cells through a word line, and a second peripheral region where bulk voltage switches are connected to bulk regions of the LV and HV switches.

Abstract: A method of forming an active region structure includes preparing a semiconductor substrate having a cell array region and a peripheral circuit region, forming upper cell mask patterns having a line shape in the cell array region, forming first and second peripheral mask patterns in the peripheral circuit region, the first and second peripheral mask patterns being stacked in sequence and covering the peripheral circuit region, and upper surfaces of the upper cell mask patterns forming a step difference with an upper surface of the second peripheral mask pattern, forming spacers on sidewalls of the upper cell mask patterns to expose lower portions of the upper cell mask patterns and the second peripheral mask pattern, and removing the lower portions of the upper cell mask patterns using the spacers and the first and second peripheral mask patterns as an etch mask.

Abstract: A nonvolatile memory device may include a substrate having a cell region, and a cell device isolation layer on the cell region of the substrate to define a cell active region. A floating gate may include a lower floating gate and an upper floating gate sequentially stacked on the cell active region, and a tunnel insulation pattern may be between the floating gate and the cell active region. A control gate electrode may be on the floating gate, and a blocking insulation pattern may be between the control gate electrode and the floating gate. More particularly, the upper floating gate may include a flat portion on the lower floating gate and a pair of wall portions extending upward from both edges of the flat portion adjacent to the cell device isolation layer. Moreover, a width of an upper portion of a space surrounded by the flat portion and the pair of wall portions may be larger than a width of a lower portion of the space. Related methods are also discussed.

Abstract: Trench isolated integrated circuit devices are fabricated by forming a trench including sidewalls in an integrated circuit substrate, and forming a lower device isolation layer in the trench and extending onto the trench sidewalls. The lower device isolation layer includes grooves therein, a respective one of which extends along a respective one of the sidewalls. An upper device isolation layer is formed on the lower device isolation layer and in the grooves. Trench isolated integrated circuit devices include an integrated circuit substrate including a trench having sidewalls and a lower device isolation layer in the trench and extending onto the trench sidewalls. The lower device isolation layer includes grooves therein, a respective one of which extends along a respective one of the sidewalls. An upper device isolation layer is provided on the lower device isolation layer and in the grooves.

Abstract: A method of fabricating a flash memory device. Parallel mask patterns are formed on a substrate. The substrate is etched using the mask patterns to form trenches. An insulating layer pattern is formed in the trenches and an area between the mask patterns. The mask patterns are removed to expose an upper sidewall of the insulating layer pattern that protrudes away from a top surface of the substrate. The insulating layer pattern is isotropically etched to form sloped sidewalls that protrude away from the top surface of the substrate.

Abstract: A semiconductor integrated circuit having a resistor is disclosed in which the resistor is formed by a series connection of one element having a positive temperature coefficient and another element having a negative temperature coefficient.

Abstract: A nonvolatile memory device may include a substrate having a cell region, and a cell device isolation layer on the cell region of the substrate to define a cell active region. A floating gate may include a lower floating gate and an upper floating gate sequentially stacked on the cell active region, and a tunnel insulation pattern may be between the floating gate and the cell active region. A control gate electrode may be on the floating gate, and a blocking insulation pattern may be between the control gate electrode and the floating gate. More particularly, the upper floating gate may include a flat portion on the lower floating gate and a pair of wall portions extending upward from both edges of the flat portion adjacent to the cell device isolation layer. Moreover, a width of an upper portion of a space surrounded by the flat portion and the pair of wall portions may be larger than a width of a lower portion of the space. Related methods are also discussed.

Abstract: A semiconductor integrated circuit having a resistor is disclosed in which the resistor is formed by a series connection of one element having a positive temperature coefficient and another element having a negative temperature coefficient.

Abstract: Gate structures of a non-volatile integrated circuit memory device can include a thermal oxidation layer on a substrate beneath the gate structure that defines a side wall of the gate structure. An oxygen diffusion barrier layer is on the side wall of the gate structure and a floating gate is on the thermal oxidation layer and has a curved side wall portion. Related methods are also discussed.

Abstract: A method of fabricating a flash memory device. Parallel mask patterns are formed on a substrate. The substrate is etched using the mask patterns to form trenches. An insulating layer pattern is formed in the trenches and an area between the mask patterns. The mask patterns are removed to expose an upper sidewall of the insulating layer pattern that protrudes away from a top surface of the substrate. The insulating layer pattern is isotropically etched to form sloped sidewalls that protrude away from the top surface of the substrate.

Abstract: Trench isolated integrated circuit devices are fabricated by forming a trench including sidewalls in an integrated circuit substrate, and forming a lower device isolation layer in the trench and extending onto the trench sidewalls. The lower device isolation layer includes grooves therein, a respective one of which extends along a respective one of the sidewalls. An upper device isolation layer is formed on the lower device isolation layer and in the grooves. Trench isolated integrated circuit devices include an integrated circuit substrate including a trench having sidewalls and a lower device isolation layer in the trench and extending onto the trench sidewalls. The lower device isolation layer includes grooves therein, a respective one of which extends along a respective one of the sidewalls. An upper device isolation layer is provided on the lower device isolation layer and in the grooves.

Abstract: A method of fabricating a flash memory device. Parallel mask patterns are formed on a substrate. The substrate is etched using the mask patterns to form trenches. An insulating layer pattern is formed in the trenches and an area between the mask patterns. The mask patterns are removed to expose an upper sidewall of the insulating layer pattern that protrudes away from a top surface of the substrate. The insulating layer pattern is isotropically etched to form sloped sidewalls that protrude away from the top surface of the substrate.

Abstract: Trench isolated integrated circuit devices are fabricated by forming a trench including sidewalls in an integrated circuit substrate, and forming a lower device isolation layer in the trench and extending onto the trench sidewalls. The lower device isolation layer includes grooves therein, a respective one of which extends along a respective one of the sidewalls. An upper device isolation layer is formed on the lower device isolation layer and in the grooves. Trench isolated integrated circuit devices include an integrated circuit substrate including a trench having sidewalls and a lower device isolation layer in the trench and extending onto the trench sidewalls. The lower device isolation layer includes grooves therein, a respective one of which extends along a respective one of the sidewalls. An upper device isolation layer is provided on the lower device isolation layer and in the grooves.

Abstract: Trench isolated integrated circuit devices are fabricated by forming a trench including sidewalls in an integrated circuit substrate, and forming a lower device isolation layer in the trench and extending onto the trench sidewalls. The lower device isolation layer includes grooves therein, a respective one of which extends along a respective one of the sidewalls. An upper device isolation layer is formed on the lower device isolation layer and in the grooves. Trench isolated integrated circuit devices include an integrated circuit substrate including a trench having sidewalls and a lower device isolation layer in the trench and extending onto the trench sidewalls. The lower device isolation layer includes grooves therein, a respective one of which extends along a respective one of the sidewalls. An upper device isolation layer is provided on the lower device isolation layer and in the grooves.

Abstract: Gate structures of a non-volatile integrated circuit memory device can include a thermal oxidation layer on a substrate beneath the gate structure that defines a side wall of the gate structure. An oxygen diffusion barrier layer is on the side wall of the gate structure and a floating gate is on the thermal oxidation layer and has a curved side wall portion. Related methods are also discussed.

Abstract: A method of fabricating a flash memory device. Parallel mask patterns are formed on a substrate. The substrate is etched using the mask patterns to form trenches. An insulating layer pattern is formed in the trenches and an area between the mask patterns. The mask patterns are removed to expose an upper sidewall of the insulating layer pattern that protrudes away from a top surface of the substrate. The insulating layer pattern is isotropically etched to form sloped sidewalls that protrude away from the top surface of the substrate.