Some embodiments include transistor constructions having a first insulative structure lining a recess within a base. A first conductive structure lines an interior of the first insulative structure, and a ferroelectric structure lines an interior of the first conductive structure. A second conductive structure is within a lower region of the ferroelectric structure, and the second conductive structure has an uppermost surface beneath an uppermost surface of the first conductive structure. A second insulative structure is over the second conductive structure and within the ferroelectric structure. A pair of source/drain regions are adjacent an upper region of the first insulative structure and are on opposing sides of the first insulative structure from one another.

According to one embodiment, a nonvolatile semiconductor memory device is provided. The element isolation insulating bodies form active areas extending in one direction along a surface of a semiconductor substrate in a surface region of the semiconductor substrate, and partition the surface region into the active areas. The tunnel insulating films are formed on the active areas respectively. The floating gate electrodes are formed on the tunnel insulating films respectively. The inter-gate insulating films are formed on the floating gate electrodes. The control gate electrodes are provided on the inter-gate insulating films. The source regions and drain regions are formed in the active areas respectively. Each of the active areas has steps at side surfaces. A width of a portion of each of the active areas deeper than the steps is larger than that of a portion of each of the active areas shallower than the steps.

The disclosure, belonging to the technological field of semiconductor memory, specifically relates to a semi-floating-gate device which comprises at least a semiconductor substrate, a source region, a drain region, a floating gate, a control gate, a perpendicular channel region and a gated p-n junction diode used to connect the floating gate and the substrate. The semi-floating-gate device disclosed in the disclosure using the floating gate to store information and realizing charging or discharging of the floating gate through a gated p-n junction diode boasts small unit area, high chip density, low operating voltage in data storage and strong ability in data retain.

A method includes forming a shallow trench isolation (STI) region in a substrate, the STI region comprising an etch stop layer; etching the STI region by a first etch to the etch stop layer to form a recess in the STI region; and forming a floating gate, the floating gate comprising a portion that extends into the recess in the STI region, wherein the etch stop layer separates the portion of the floating gate that extends into the recess in the STI region from the substrate.

The present invention provides a semiconductor device, including a substrate with a memory region and a logic region, the substrate having a recess disposed in the memory region, a logic gate stack disposed in the logic region, and a non-volatile memory disposed in the recess. The non-volatile memory includes at least two floating gates and at least two control gates disposed on the floating gates, where each floating gate has a step-shaped bottom, and the step-shaped bottom includes a first bottom surface and a second bottom surface lower than the first bottom surface.

A semiconductor structure includes a nonvolatile memory cell including a first nonvolatile bit storage element and a second nonvolatile bit storage element which have a common source region provided in a semiconductor material and a common control gate structure. Each nonvolatile bit storage element includes a drain region, a channel region, a select gate structure, a floating gate structure and an erase gate structure. The channel region has a select gate side portion and a floating gate side portion. The select gate structure is provided at the select gate side portion of the channel region and the floating gate structure is provided at the floating gate side portion of the channel region. The erase gate structure is provided above the select gate structure and adjacent the floating gate structure. The control gate structure extends above the floating gate structures of the first and second nonvolatile bit storage elements.

A method for forming a semiconductor device includes forming first and second hard mask layers overlying a semiconductor substrate and forming trenches through the second hard mask, the first hard mask, and into the substrate. A dielectric material is formed in the trenches to form shallow trench isolation regions, removing the second hard mask layer, and a floating gate material is formed overlying the first hard mask and the trenches. The method further includes repeating at least twice a process of forming a buffer layer over the floating gate material and using a polishing process to remove a portion of the buffer layer and a top portion of the floating gate material. Next, a dry etch process to remove a portion of the floating gate material above the shallow trench isolation regions and the remaining portions of the buffer layer to form floating gate structures.

A semiconductor structure and a manufacturing method thereof are provided. The semiconductor structure includes a semiconductor substrate, a non-volatile memory cell, and a gate stack. The non-volatile memory cell is formed in the semiconductor substrate, and a top surface of the non-volatile memory cell is coplanar with or below a top surface of the semiconductor substrate. The gate stack is formed on the semiconductor substrate.

Some embodiments include transistor constructions having a first insulative structure lining a recess within a base. A first conductive structure lines an interior of the first insulative structure, and a ferroelectric structure lines an interior of the first conductive structure. A second conductive structure is within a lower region of the ferroelectric structure, and the second conductive structure has an uppermost surface beneath an uppermost surface of the first conductive structure. A second insulative structure is over the second conductive structure and within the ferroelectric structure. A pair of source/drain regions are adjacent an upper region of the first insulative structure and are on opposing sides of the first insulative structure from one another.

Various embodiments provide a memory cell that includes a vertical selection gate, a floating gate extending above the substrate, wherein the floating gate also extends above a portion of the vertical selection gate, over a non-zero overlap distance, the memory cell comprising a doped region implanted at the intersection of a vertical channel region extending opposite the selection gate and a horizontal channel region extending opposite the floating gate.