A method for manufacturing a semiconductor device includes providing a semiconductor substrate, forming a first dielectric layer having a first thickness on the semiconductor substrate, forming a first opening having a first width in the first dielectric layer and exposing a surface of the semiconductor substrate, forming a spacer on opposite sidewalls of the first opening, forming a second dielectric layer having a second thickness on the exposed surface of the semiconductor substrate in a middle region of the first opening, removing the spacer to form a second opening having a first opening portion and a second opening portion on opposite sides of the second dielectric layer, and forming a third dielectric layer having a third thickness on the first and second opening portions of the second opening. The third thickness is smaller than the first thickness and the second thickness.

A structure with which the zero current of a field effect transistor using a conductor-semiconductor junction can be reduced is provided. A floating electrode (102) including a conductor or a semiconductor and being enclosed by an insulator (104) is formed between a semiconductor layer (101) and a gate (105) so as to cross the semiconductor layer (101) and the floating electrode (102) is charged, whereby carriers are prevented from flowing from a source electrode (103a) or a drain electrode (103b). Accordingly, a sufficiently low carrier concentration can be kept in the semiconductor layer (101) and thus the zero current can be reduced.

A non-volatile memory device includes a semiconductor substrate, a well region situated on the semiconductor substrate, a floating gate situated on the well region, a floating gate channel region, a control gate situated on both sides of the floating gate, a control gate channel region, and an ion implantation area for regulating a program threshold voltage integrally formed between an area underneath of the floating gate and the control gate and a foreside of the well region, wherein a doping concentration of the ion implantation area for regulating a program threshold voltage is greater than a doping concentration of the well region. Therefore, the non-volatile memory device of examples integrally forms an ion implantation area for regulating a program threshold voltage irrespective of a channel region of a floating gate and a control gate so as to guarantee durability of a non-volatile memory device.

A flash memory cell structure includes a semiconductor substrate, a pad dielectric layer, a floating gate, a control gate, and a blocking layer. The pad dielectric layer is disposed on the semiconductor substrate. The floating gate is disposed over the pad dielectric layer, in which the floating gate has a top surface opposite to the pad dielectric layer, and the top surface includes at least one recess formed thereon. The control gate is disposed over the top surface of the floating gate. The blocking layer is disposed between the floating gate and the control gate.

A method comprises doping a lower portion of a nanowire to form a first drain/source region, wherein the nanowire is formed over a substrate, doping an upper portion of the nanowire to form a second drain/source region, doping a middle portion of the nanowire to form a channel region, wherein the channel region is between the first drain/source region and the second drain/source region, forming a ring-shaped gate structure surrounding a lower portion of the channel region, wherein the ring-shaped gate structure comprises a vertical portion of a first work-function metal layer and depositing a low-resistivity gate metal layer over a horizontal portion of the first work-function metal layer, wherein the low-resistivity gate metal layer is electrically coupled to the vertical portion of the first work-function metal layer through the horizontal portion of the first work-function metal layer.

A semiconductor device includes a substrate, a tunnel insulation pattern on the substrate, a charge storage pattern on the tunnel insulation pattern, a dielectric pattern having a width smaller than a width of the charge storage pattern on the charge storage pattern, a control gate having a width greater than the width of the dielectric pattern on the dielectric pattern, and a metal-containing gate on the control gate.

A semiconductor device manufacturing method includes forming a silicon layer by epitaxial growth over a semiconductor substrate having a first area and a second area; forming a first gate oxide film by oxidizing the silicon layer; removing the first gate oxide film from the second area, while maintaining the first gate oxide film in the first area; thereafter, increasing a thickness of the first gate oxide film in the first area and simultaneously forming a second gate oxide film by oxidizing the silicon layer in the second area; and forming a first gate electrode and a second gate electrode over the first gate oxide film and the second gate oxide film, respectively, wherein after the formation of the first and second gate electrodes, the silicon layer in the first area is thicker than the silicon layer in the second area.

A memory cell formed in a semiconductor substrate, includes a selection gate extending vertically in a trench made in the substrate, and isolated from the substrate by a first layer of gate oxide, a horizontal floating gate extending above the substrate and isolated from the substrate by a second layer of gate oxide, and a horizontal control gate extending above the floating gate. The selection gate covers a lateral face of the floating gate. The floating gate is separated from the selection gate only by the first layer of gate oxide, and separated from a vertical channel region, extending in the substrate along the selection gate, only by the second layer of gate oxide.

A semiconductor memory device includes a semiconductor substrate, a first insulating film disposed on the semiconductor substrate, a first conductive film disposed on the first insulating film, a second insulating film disposed on the first conductive film, a second conductive film disposed on the second insulating film, a first electrode disposed on the first conductive film through an opening formed in the second conductive film and the second insulating film, and having a first width, a second electrode that is formed on the first electrode and having a second width, and a wiring layer that is formed on the second electrode. A first width of the first electrode is wider than a second width of the second electrode.

A nonvolatile memory device may include: an isolation layer formed in a substrate and defining an active region; a control plug formed over the isolation layer; a floating gate formed over the substrate and including a plurality of fingers adjacent to the control plug with a gap provided therebetween; and a charge blocking layer formed on sidewalls of the floating gate so as to fill the gap. The control plug may include: a first control plug formed between the plurality of fingers and having sidewalls facing inner walls of the fingers; and a second control plug formed outside the floating gate and having sidewalls facing outer walls of the fingers.