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: Non-volatile memory devices and methods for fabricating non-volatile memory devices are disclosed. More specifically, split gate memory devices are provided having frameworks that provide increased floating gate coupling ratios, thereby enabling enhanced programming and erasing efficiency and performance.

Abstract: A non-volatile memory device comprises an active region disposed in a predetermined region of a semiconductor substrate, a selection gate electrode crossing over the active region, and a floating gate electrode disposed on the active region parallel to the selection gate electrode and spaced apart from the selection gate electrode. The non-volatile memory device further comprises a tunnel insulating layer intervening between the active region and each of the selection gate electrode and the floating gate electrode, a separation insulating pattern intervening between the selection gate electrode and the floating gate electrode, an erasing gate electrode disposed over the floating gate electrode and crossing over the active region parallel to the selection gate electrode, and an erasing gate insulating layer intervening between the erasing gate electrode and the floating gate electrode. The selection gate electrode is formed without a photoresist pattern.

Abstract: A non-volatile memory device includes isolation layers, a cell trench, a floating gate, a common source region and a word line. The isolation layers define an active region of a substrate. The cell trench is formed in the active region. The cell trench extends in a first direction. The floating gate is formed on the active region and in the cell trench. The common source region is formed on the active region adjacent a second side face of the floating gate and extends in a second direction substantially perpendicular to the first direction. The word line is formed on the active region, which is adjacent to a first side face of the floating gate opposite to the second side face, and the isolation layers and in the cell trench. The word line extends in the second direction.

Abstract: An etchant for removing an indium oxide layer includes sulfuric acid as a main oxidizer, an auxiliary oxidizer such as H3PO4, HNO3, CH3COOH, HClO4, H2O2, and a Compound A that is obtained by mixing potassium peroxymonosulfate (2KHSO5), potassium bisulfate (KHSO4), and potassium sulfate (K2SO4) together in the ratio of 5:3:2, an etching inhibitor comprising an ammonium-based material, and water. The etchant may remove desired portions of the indium oxide layer without damage to a photoresist pattern or layers underlying the indium oxide layer.

Abstract: Non-volatile memory devices and methods for fabricating non-volatile memory devices are disclosed. More specifically, split gate memory devices are provided having frameworks that provide increased floating gate coupling ratios, thereby enabling enhanced programming and erasing efficiency and performance.

Abstract: A semiconductor flash memory device. The flash memory device includes a floating gate electrode disposed in a recess having slanted sides in a semiconductor substrate. A gate insulation film is interposed between the floating gate electrode and the semiconductor substrate. A control gate electrode is disposed over the floating gate electrode. The floating gate electrode includes projections adjacent to the slanted sides of the recess.

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: 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 nonvolatile memory device Includes an active region defined in a semiconductor substrate and a control gate electrode crossing over the active region. A gate insulating layer is interposed between the control gate electrode and the active reigon. A floating gate is formed in the active region to penetrate the control gate electrode and extend to a predetermined depth into the semiconductor substrate. A tunnel insulating layer is successively interposed between the control gate electrode and the floating gate, and between the semiconductor substrate and the floating gate. The floating gate may be formed after a trench is formed by sequentially etching a control gate conductive layer and the semiconductor substrate, and a tunnel insulating layer is formed on the trench and sidewalls of the control gate conductive layer. The floating gate is formed in the trench to extend into a predetermined depth into the semiconductor substrate.

Abstract: A nonvolatile memory device includes a liner covering a sidewall and bottom of a trench that defines an active field in a substrate and a field isolation film disposed on the liner which fills the trench. The nonvolatile memory device further includes a floating gate disposed on the active field having an edge of which covers the liner, a tunnel insulation film interposed between the active field and the floating gate and a charge diffusion barrier interposed between the liner and the floating gate.

Abstract: A split gate memory device and fabricating method thereof, wherein gate insulating and polysilicon layers are sequentially formed on a substrate. The polysilicon layer is patterned and a capping insulating layer is formed on portions thereof. A pair of self-aligned control gates having identical bottom widths are formed with a tunnel insulating layer interposed between the control gates and sidewalls of the polysilicon layer pattern and capping insulating layer. The tunnel insulating layer, patterned polysilicon layer and gate insulating layer are selectively etched to expose a portion of the substrate thereby forming a pair of floating gates. Ions are implanted into the exposed substrate and portions of the substrate adjoining the control gates to form a common source region and a drain region, respectively. The capping insulating layer on the floating gate protects an acute section of the tunnel insulating layer from attack during the etching and ion implantation.

Abstract: A flash memory device including a tunnel dielectric layer, a floating gate layer, an interlayer dielectric layer and at least two mold layers formed on a semiconductor substrate and a method of manufacturing the same are provided. By sequentially patterning the layers, a first mold layer pattern and a floating gate layer pattern aligned with each other are formed. Exposed portions of side surfaces of the first mold layer pattern are selectively lateral etched, thereby forming a first mold layer second pattern having grooves in its sidewalls. A gate dielectric layer is formed on the semiconductor substrate adjacent to the floating gate layer pattern. A control gate having a width that is determined by the grooves in the second mold layer pattern is formed on the gate dielectric layer. By removing the first mold layer second pattern, spacers are formed on sidewalls of the control gate.

Abstract: A flash memory device including a tunnel dielectric layer, a floating gate layer, an interlayer dielectric layer and at least two mold layers formed on a semiconductor substrate and a method of manufacturing the same are provided. By sequentially patterning the layers, a first mold layer pattern and a floating gate layer pattern aligned with each other are formed. Exposed portions of side surfaces of the first mold layer pattern are selectively lateral etched, thereby forming a first mold layer second pattern having grooves in its sidewalls. A gate dielectric layer is formed on the semiconductor substrate adjacent to the floating gate layer pattern. A control gate having a width that is determined by the grooves in the second mold layer pattern is formed on the gate dielectric layer. By removing the first mold layer second pattern, spacers are formed on sidewalls of the control gate.

Abstract: A tunneling dielectric layer, a charge trapping layer, a first length defining layer, and a second length defining layer are sequentially deposited on a semiconductor substrate. These layers are sequentially patterned. Exposed both sidewalls of the first length defining layer first pattern are recessed by selective side etching. After forming a blocking layer for covering the exposed charge trapping layer and a gate layer for filling the recessed portion, the gate layer is patterned to form spacer shaped gates. Dopant regions for source and drain regions are formed on the semiconductor substrate adjacent the gates.

Abstract: Embodiments of the invention include a gate insulating layer formed on a semiconductor substrate; a spacer-type floating gate and a spacer-type dummy pattern, which are formed on the gate insulating layer and separated apart from each other, the floating gate and the dummy pattern having round surfaces that face outward; a pair of insulating spacers, which are formed on a sidewall of the floating gate and a sidewall of the dummy pattern which face each other; a control gate formed in a self-aligned manner between the pair of insulating spacers; a tunnel insulating layer interposed between the floating gate and the control gate; and source and drain regions formed in the semiconductor substrate outside the floating gate and the dummy pattern.

Abstract: In a method of forming a silicon-oxide-nitride-oxide-silicon (SONOS) type nonvolatile memory device, a plurality of first gates may be formed on a semiconductor substrate. A plurality of charge storage spacers may be formed on the plurality of first gates so that a given charge storage spacer may be disposed on a sidewall of a given first gate. A plurality of second gates may be disposed on the plurality of first gates so that a given second gate is on a sidewall of a given first gate and covers a given charge storage spacer.

Abstract: Non-volatile memory devices and methods for fabricating non-volatile memory devices are disclosed. More specifically, split gate memory devices are provided having frameworks that provide increased floating gate coupling ratios, thereby enabling enhanced programming and erasing efficiency and performance.

Abstract: In a method of forming a silicon-oxide-nitride-oxide-silicon (SONOS) type nonvolatile memory device, a plurality of first gates may be formed on a semiconductor substrate. A plurality of charge storage spacers may be formed on the plurality of first gates so that a given charge storage spacer may be disposed on a sidewall of a given first gate. A plurality of second gates may be disposed on the plurality of first gates so that a given second gate is on a sidewall of a given first gate and covers a given charge storage spacer.

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.