Abstract: Provided are a non-volatile memory device having an improved electric characteristic and a method of manufacturing the non-volatile memory device, where the non-volatile memory device includes a substrate having a sloped portion formed therein, a first gate electrode pattern having a stacked structure in which an electric charge tunneling layer pattern, an electric charge trapping layer pattern, an electric charge shielding layer pattern, and a storage gate electrode pattern are conformably stacked on the sloped portion, a gate insulating layer pattern extending from a side of the first gate electrode pattern to the substrate, a second gate electrode pattern formed on the gate insulating layer pattern, a first junction region arranged at a side wall of the first gate electrode pattern, which does not face the second gate electrode pattern, and formed in the substrate, and a second junction region arranged at a side wall of the second gate electrode pattern, which does not face the first gate electrode pattern

Abstract: A semiconductor device includes transistors with a vertical gate electrode. In a transistor structure, a semiconductor pattern has first and second sides facing in a transverse direction, and third and fourth sides facing in a longitudinal direction. Gate patterns are disposed adjacent to the first and second sides of the semiconductor pattern. Impurity patterns directly contact the third and fourth sides of the semiconductor pattern. A gate insulating pattern is interposed between the gate patterns and the semiconductor pattern.

Abstract: A non-volatile memory device includes a floating gate formed on a substrate with a gate insulation layer interposed therebetween, a tunnel insulation layer formed on the floating gate, a select gate electrode inducing charge introduction through the gate insulation layer, and a control gate electrode inducing charge tunneling occurring through the tunnel insulation layer. The select gate electrode is insulated from the control gate electrode. According to the non-volatile memory device, a select gate electrode and a control gate electrode are formed on a floating gate, and thus a voltage is applied to the respective gate electrodes to write and erase data.

Abstract: Provided are non-volatile split-gate memory cells having self-aligned floating gate and the control gate structures and exemplary processes for manufacturing such memory cells that provide improved dimensional control over the relative lengths and separation of the split-gate elements. Each control gate includes a projecting portion that extends over at least a portion of the associated floating gate with the size of the projecting portion being determined by a first sacrificial polysilicon spacer that, when removed, produces a concave region in an intermediate insulating structure. The control gate is then formed as a polysilicon spacer adjacent the intermediate insulating structure, the portion of the spacer extending into the concave region determining the dimension and spacing of the projecting portion and the thickness of the interpoly oxide (IPO) separating the upper portions of the split-gate electrodes thereby providing improved performance and manufacturability.

Abstract: Provided are a non-volatile memory device and a method of manufacturing the same. The non-volatile memory device includes a gate insulating layer having a tunneling window formed therein. The tunneling window has a predetermined width parallel to a channel length direction and has a predetermined length perpendicular to the channel length direction on a semiconductor substrate. The non-volatile memory device further includes a lower floating gate including a first lower floating gate formed on the gate insulating layer and a second lower floating gate spaced a predetermined interval apart from the first lower floating gate, and wherein the tunneling window and a portion of the gate insulating layer which is adjacent to the tunneling window are partially exposed in a region between the first lower floating gate and the second lower floating gate.

Abstract: Provided are a local SONOS-type memory device and a method of manufacturing the same. The device includes a gate oxide layer formed on a silicon substrate; a conductive spacer and a dummy spacer, which are formed on the gate oxide layer and separated apart from each other, the conductive spacer and the dummy spacer having round surfaces that face outward; a pair of insulating spacers formed on a sidewall of the conductive spacer and a sidewall of the dummy spacer which face each other; an ONO layer formed in a self-aligned manner between the pair of insulating spacers; a conductive layer formed on the ONO layer in a self-aligned manner between the pair of insulating spacers; and source and drain regions formed in the silicon substrate outside the conductive spacer and the dummy spacer.

Abstract: In a local-length nitride SONOS device and a method for forming the same, a local-length nitride floating gate structure is provided for mitigating or preventing lateral electron migration in the nitride floating gate. The structure includes a thin gate oxide, which leads to devices having a lower threshold voltage. In addition, the local-length nitride layer is self-aligned, which prevents nitride misalignment, and therefore leads to reduced threshold voltage variation among the devices.

Abstract: A split gate type nonvolatile semiconductor memory device and a method of fabricating a split gate type nonvolatile semiconductor memory device are provided. A gate insulating layer and a floating-gate conductive layer are formed on a semiconductor substrate. A mask layer pattern is formed on the floating-gate conductive layer to define a first opening extending in a first direction. First sacrificial spacers having a predetermined width are formed on both sidewalls corresponding to the mask layer pattern. An inter-gate insulating layer is formed on the floating-gate conductive layer. The first sacrificial spacers are removed, and the floating-gate conductive layer is etched until the gate insulating layer is exposed. A tunneling insulating layer is formed on an exposed portion of the floating-gate conductive layer. A control-gate conductive layer is formed on a surface of the semiconductor substrate. Second sacrificial spacers having predetermined widths are formed on the control-gate conductive layer.

Abstract: In a method for forming a semiconductor device and a semiconductor device formed in accordance with the method, a thin dielectric layer is provided between a lower conductive layer and an upper conductive layer. In one embodiment, the thin dielectric layer comprises an inter-gate dielectric layer, the lower conductive layer comprises a floating gate and the upper dielectric layer comprises a control gate of a transistor, for example, a non-volatile memory cell transistor. The thin dielectric layer is formed using a heat treating process that results in reduction of surface roughness of the underlying floating gate, and results in a thin silicon oxy-nitride layer being formed on the floating gate. In this manner, the thin dielectric layer provides for increased capacitive coupling between the lower floating gate and the upper control gate. This also leads to a lowered programming voltage, erasing voltage and read voltage for the transistor, while maintaining the threshold voltage in a desired range.

Abstract: In a method for forming a semiconductor device and a semiconductor device formed in accordance with the method, a thin dielectric layer is provided between a lower conductive layer and an upper conductive layer. In one embodiment, the thin dielectric layer comprises an inter-gate dielectric layer, the lower conductive layer comprises a floating gate and the upper dielectric layer comprises a control gate of a transistor, for example, a non-volatile memory cell transistor. The thin dielectric layer is formed using a heat treating process that results in reduction of surface roughness of the underlying floating gate, and results in a thin silicon oxy-nitride layer being formed on the floating gate. In this manner, the thin dielectric layer provides for increased capacitive coupling between the lower floating gate and the upper control gate. This also leads to a lowered programming voltage, erasing voltage and read voltage for the transistor, while maintaining the threshold voltage in a desired range.

Abstract: A method of manufacturing a split gate type nonvolatile semiconductor memory device in which control gates are formed by a self aligning process.

Abstract: Provided are a local SONOS-type memory device and a method of manufacturing the same. The device includes a gate oxide layer formed on a silicon substrate; a conductive spacer and a dummy spacer, which are formed on the gate oxide layer and separated apart from each other, the conductive spacer and the dummy spacer having round surfaces that face outward; a pair of insulating spacers formed on a sidewall of the conductive spacer and a sidewall of the dummy spacer which face each other; an ONO layer formed in a self-aligned manner between the pair of insulating spacers; a conductive layer formed on the ONO layer in a self-aligned manner between the pair of insulating spacers; and source and drain regions formed in the silicon substrate outside the conductive spacer and the dummy spacer.

Abstract: A split gate type nonvolatile semiconductor memory device and a method of fabricating a split gate type nonvolatile semiconductor memory device are provided. A gate insulating layer and a floating-gate conductive layer are formed on a semiconductor substrate. A mask layer pattern is formed on the floating-gate conductive layer to define a first opening extending in a first direction. First sacrificial spacers having a predetermined width are formed on both sidewalls corresponding to the mask layer pattern. An inter-gate insulating layer is formed on the floating-gate conductive layer. The first sacrificial spacers are removed, and the floating-gate conductive layer is etched until the gate insulating layer is exposed. A tunneling insulating layer is formed on an exposed portion of the floating-gate conductive layer. A control-gate conductive layer is formed on a surface of the semiconductor substrate. Second sacrificial spacers having predetermined widths are formed on the control-gate conductive layer.

Abstract: An EEPROM device includes a device isolation layer disposed at a predetermined region of a semiconductor substrate to define active regions, a pair of control gates crossing the device isolation layers and an active region, a pair of selection gates interposed between the control gates to cross the device isolation layers and the active region and a floating gate and an intergate dielectric pattern stacked sequentially between the control gates and the active region The EEPROM device further includes a gate insulation layer of a memory transistor interposed between the floating gate and the active region and a tunnel insulation layer thinner than the gate insulation layer of the memory transistor and a gate insulation layer of a selection transistor interposed between the selection gates and the active region. The tunnel insulation layer is aligned at one side adjacent to the floating gate.

Abstract: A non-volatile memory device includes a control gate electrode disposed on a substrate with a first insulation layer interposed therebetween and a floating gate disposed in a hole exposing substrate through the control gate electrode and the first insulation layer. A second insulation layer is interposed between the floating gate and the substrate, and between the floating gate and the control gate.

Abstract: A method of manufacturing a split gate type nonvolatile semiconductor memory device in which control gates are formed by a self aligning process.

Abstract: In one embodiment, a semiconductor device includes a semiconductor substrate having a first junction region and a second junction region. An insulated floating gate is disposed on the substrate. The floating gate at least partially overlaps the first junction region. An insulated program gate is disposed on the floating gate. The program gate has a curved upper surface. The semiconductor device further includes an insulated erase gate disposed on the substrate and adjacent the floating gate. The erase gate partially overlaps the second junction region.

Abstract: A silicon-oxide-nitride-oxide-silicon (SONOS) memory cell and a method of forming the same are disclosed. The SONOS memory cell includes a substrate in which a recessed region having at least one side wall is arranged and a trap storage pattern with which the recessed region is filled with a first insulating film is interposed. A control gate electrode is arranged on the top surface of the substrate and the top surface of the trap storage pattern with a second insulating film interposed. First and second source/drain regions are arranged in the substrate on both sides of the control gate electrode. The top surface of the trap storage pattern is flat and is at least as high as the top surface of the substrate.

Abstract: A nonvolatile semiconductor device and a method of fabricating the same are provided. The nonvolatile semiconductor device includes a semiconductor body formed on a substrate to be elongated in one direction and having a cross section perpendicular to a main surface of the substrate and elongated direction, the cross section having a predetermined curvature, a channel region partially formed along the circumference of the semiconductor body, a tunneling insulating layer disposed on the channel region, a floating gate disposed on the tunneling insulating layer and electrically insulated from the channel region, an intergate insulating layer disposed on the floating gate, a control gate disposed on the intergate insulating layer and electrically insulated from the floating gate, and source and drain regions which are aligned with both sides of the control gate and formed within the semiconductor body.

Abstract: A flash memory device according to the present invention includes a semiconductor fin including a top surface and a side surface originated from different crystal planes. The flash memory device comprises: insulating layers having different thicknesses formed on a side surface and a top surface of the semiconductor fin, a storage electrode, a gate insulating layer and a control gate electrode sequentially formed on the insulating layers. A thin insulating layer enables charges to be injected or emitted through it, and a thick insulating layer increases a coupling ratio. Accordingly, it is possible to increase an efficiency of a programming or an erase operation of a flash memory device.