Some embodiments of the present disclosure relate to a flash memory device. The flash memory device includes first and second individual source/drain (S/D) regions spaced apart within a semiconductor substrate. A common S/D region is arranged laterally between the first and second individual S/D regions, and is separated from the first individual S/D region by a first channel region and is separated from the second individual S/D region by a second channel region. An erase gate is arranged over the common S/D. A floating gate is disposed over the first channel region and is arranged to a first side of the erase gate. A control gate is disposed over the floating gate. A wordline is disposed over the first channel region and is spaced apart from the erase gate by the floating gate and the control gate. An upper surface of the wordline is a concave surface.

A method of fabricating a semiconductor device including forming a charge storage layer, and forming a first tunnel insulating layer covering the charge storage layer, the forming of the first tunnel insulating layer including heat treating the charge storage layer.

In an integrated-circuit memory, performance is increased by reducing an electrical contact resistance between a metal layer and an upper poly layer (a control gate poly). The electrical contact resistance is reduced by increasing the thickness of a silicide layer between the metal layer and the upper poly layer. The memory has a memory cell region and a non-memory cell region. The thickness of the silicide layer is typically restricted by consideration of integrated-circuit fabrication geometry for each memory cell not to exceed a predetermined aspect ratio. The present implementation allows independent optimization of the thickness of silicide layer in the memory cells region and the non-memory cell region. In particular, in the non-memory cell region, a thicker silicide layer significantly improves the contact resistance of a slit contact for components having the upper poly layer in contact with a lower poly layer (a floating gate poly).

A semiconductor device includes a first mono-crystallized layer including first transistors, and a first metal layer forming at least a portion of connections between the first transistors; and a second layer including second transistors, the second transistors including mono-crystalline material, the second layer overlying the first metal layer, wherein the first metal layer includes aluminum or copper, and wherein the second layer is less than one micron in thickness and includes logic cells.

A device includes a semiconductor substrate including an active region. The active region includes a first sidewall. An isolation region extends from a top surface of the semiconductor substrate into the semiconductor substrate. The isolation region has a second sidewall, wherein a lower portion of the first sidewall joins a lower portion of the second sidewall to form an interface. A dielectric spacer is disposed on an upper portion of the first sidewall. A silicide region is over and contacting the active region. A sidewall of the silicide region contacts the dielectric spacer, and the dielectric spacer has a top surface substantially lower than a top surface of the silicide region.

A semiconductor structure includes a nonvolatile memory cell including a source region, a channel region and a drain region that are provided in a semiconductor material. The channel region includes a first portion adjacent the source region and a second portion between the first portion of the channel region and the drain region. An electrically insulating floating gate is provided over the first portion of the channel region. The nonvolatile memory cell further includes a select gate and a control gate. The first portion of the select gate is provided over the second portion of the channel region. The second portion of the select gate is provided over a portion of the floating gate that is adjacent to the first portion of the select gate. The control gate is provided over the floating gate and adjacent to the second portion of the select gate.

An IC may include an array of memory cells formed in a semiconductor, including memory cells arranged in rows and columns, each memory cell may include a floating body region defining at least a portion of a surface of the memory cell, the floating body region having a first conductivity type; a buried region located within the memory cell and located adjacent to the floating body region, wherein the buried region has a second conductivity type, wherein the floating body region is bounded on a first side by a first insulating region having a first thickness and on a second side by a second insulating region having a second thickness, and a gate region above the floating body region and the second insulating region and is insulated from the floating body region by an insulating layer; and control circuitry configured to provide electrical signals to said buried region.

An integrated circuit including a link or string of semiconductor memory cells, wherein each memory cell includes a floating body region for storing data. The link or siring includes at least one contact configured to electrically connect the memory cells to at least one control line, and the number of contacts in the string or link is the same as or less than the number of memory cells in the string or link.

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 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.