Abstract: Provided is a fabricating method of a nonvolatile memory. The fabricating method includes forming a plurality of gates extending in a first direction on a substrate to be adjacent to each other, forming a gap-fill layer filling at least a portion of a space between the plurality of gates, forming a supporter pattern supporting the plurality of gates on the plurality of gates and the gap-fill layer, and forming an air gap in the space between the plurality of gates by removing the gap-fill layer.

Abstract: Methods of forming nonvolatile memory devices include forming first and second floating gate electrodes of first and second nonvolatile memory cells, respectively, at side-by-side locations on a substrate. The substrate is selectively etched to define a trench therein extending between the first and second floating gate electrodes. The trench is at least partially filled with a first electrical insulation pattern. An inorganic polysilazane-type spin-on-glass (SOG) layer is conformally deposited on the first and second floating gate electrodes and on the first electrical insulation pattern and then partially removed.

Abstract: High-voltage MOS transistors with a floated drain-side auxiliary gate are provided. The high-voltage MOS transistors include a source region and a drain region provided in a semiconductor substrate. A main gate electrode is disposed over the semiconductor substrate between the drain region and the source region. A lower drain-side auxiliary gate and an upper drain-side auxiliary gate are sequentially stacked over the semiconductor substrate between the main gate electrode and the drain region. The lower drain-side auxiliary gate is electrically insulated from the semiconductor substrate, the main gate electrode and the upper drain-side auxiliary gate. Methods of fabricating the high-voltage MOS transistors are also provided.

Abstract: A NAND includes a device isolation pattern disposed in a region of a substrate defining a plurality of active regions. Memory transistors having memory gate patterns, constituting a cell string, cross the plurality of active regions. Select transistors are disposed over the memory transistors, and lower plugs are disposed on each side of the cell string to electrically connect the plurality of active regions on both sides of the cell string and the select transistors.

Abstract: A NAND includes a device isolation pattern disposed in a region of a substrate defining a plurality of active regions. Memory transistors having memory gate patterns, constituting a cell string, cross the plurality of active regions. Select transistors are disposed over the memory transistors, and lower plugs are disposed on each side of the cell string to electrically connect the plurality of active regions on both sides of the cell string and the select transistors.

Abstract: A NAND includes a device isolation pattern disposed in a region of a substrate defining a plurality of active regions. Memory transistors having memory gate patterns, constituting a cell string, cross the plurality of active regions. Select transistors are disposed over the memory transistors, and lower plugs are disposed on each side of the cell string to electrically connect the plurality of active regions on both sides of the cell string and the select transistors.

Abstract: A nonvolatile memory device includes a semiconductor substrate, a device isolation layer, a tunnel insulation layer, a floating gate, a buried floating gate, and a control gate. A trench is in the substrate that defines an active region of the substrate adjacent to the trench. A device isolation layer is on the substrate along the trench. A tunnel insulation layer is on the active region of the substrate. A floating gate is on the tunnel insulation layer opposite to the active region of the substrate. A buried floating gate is on the device isolation layer in the trench. An intergate dielectric layer is on and extends across the floating gate and the buried floating gate. A control gate is on the intergate dielectric layer and extends across the floating gate and the buried floating gate.

Abstract: High-voltage MOS transistors with a floated drain-side auxiliary gate are provided. The high-voltage MOS transistors include a source region and a drain region provided in a semiconductor substrate. A main gate electrode is disposed over the semiconductor substrate between the drain region and the source region. A lower drain-side auxiliary gate and an upper drain-side auxiliary gate are sequentially stacked over the semiconductor substrate between the main gate electrode and the drain region. The lower drain-side auxiliary gate is electrically insulated from the semiconductor substrate, the main gate electrode and the upper drain-side auxiliary gate. Methods of fabricating the high-voltage MOS transistors are also provided.

Abstract: A NAND includes a device isolation pattern disposed in a region of a substrate defining a plurality of active regions. Memory transistors having memory gate patterns, constituting a cell string, cross the plurality of active regions. Select transistors are disposed over the memory transistors, and lower plugs are disposed on each side of the cell string to electrically connect the plurality of active regions on both sides of the cell string and the select transistors.

Abstract: A nonvolatile memory device includes a semiconductor substrate, a device isolation layer, a tunnel insulation layer, a floating gate, a buried floating gate, and a control gate. A trench is in the substrate that defines an active region of the substrate adjacent to the trench. A device isolation layer is on the substrate along the trench. A tunnel insulation layer is on the active region of the substrate. A floating gate is on the tunnel insulation layer opposite to the active region of the substrate. A buried floating gate is on the device isolation layer in the trench. An intergate dielectric layer is on and extends across the floating gate and the buried floating gate. A control gate is on the intergate dielectric layer and extends across the floating gate and the buried floating gate.