An improvement is achieved in the performance of a semiconductor device having a nonvolatile memory. A memory cell of the nonvolatile memory includes a control gate electrode formed over a semiconductor substrate via a first insulating film and a memory gate electrode formed over the semiconductor substrate via a second insulating film to be adjacent to the control gate electrode via the second insulating film. The second insulating film includes a third insulating film made of a silicon dioxide film, a fourth insulating film made of a silicon nitride film over the third insulating film, and a fifth insulating film over the fourth insulating film. The fifth insulating film includes a silicon oxynitride film. Between the memory gate electrode and the semiconductor substrate, respective end portions of the fourth and fifth insulating films are located closer to a side surface of the memory gate electrode than an end portion of a lower surface of the memory gate electrode. Between the memory gate electrode and the semiconductor substrate, in a region where the second insulating film is not formed, another silicon dioxide film is embedded.

Disclosed herein is a semiconductor device comprising a first dielectric disposed over a channel region of a transistor formed in a substrate and a gate disposed over the first dielectric. The semiconductor device further includes a second dielectric disposed vertically, substantially perpendicular to the substrate, at an edge of the gate, and a spacer disposed proximate to the second dielectric. The spacer includes a cross-section with a perimeter that includes a top curved portion and a vertical portion substantially perpendicular to the substrate. The perimeter further includes a discontinuity at an interface of the top curved portion with the vertical portion. Further, disclosed herein are methods associated with the fabrication of the aforementioned semiconductor device.

A p-i-n junction structure is formed within a memory film laterally surrounded by an alternating plurality of electrically insulating layers and electrically conductive layers to provide a three-dimensional memory structure. The p-i-n junction includes a lower junction between an intrinsic semiconductor channel portion and a lower doped semiconductor portion and an upper junction between the intrinsic semiconductor channel portion and an upper doped semiconductor portion. The memory film can be subsequently formed on a sidewall of the memory opening, and the intrinsic semiconductor channel portion can be deposited on the memory opening and the lower doped semiconductor portion. The upper doped semiconductor portion can be formed above a topmost electrically conductive layer. The lower doped semiconductor portion can provide hole charge carriers for electrical current.

A non-volatile memory has an array of non-volatile memory cells. Each of the non-volatile memory cells includes a coupling device formed on a first well, a read device, a floating gate device formed on a second well and coupled to the coupling device, a program device formed on the second well, and an erase device formed on a third well and coupled to the first floating gate device. The read device, the program device, and the erase device are formed on separate wells so as to separate the cycling counts of a read operation, a program operation and an erase operation of the non-volatile memory cell.

A memory cell formed by forming a trench in the surface of a substrate. First and second spaced apart regions are formed in the substrate with a channel region therebetween. The first region is formed under the trench. The channel region includes a first portion that extends along a sidewall of the trench and a second portion that extends along the surface of the substrate. A charge trapping layer in the trench is adjacent to and insulated from the first portion of the channel region for controlling the conduction of the channel region first portion. An electrically conductive gate in the trench is adjacent to and insulated from the charge trapping layer and from the first region and is capacitively coupled to the charge trapping layer. An electrically conductive control gate is disposed over and insulated from the second portion of the channel region for controlling its conduction.

A nonvolatile semiconductor memory device, includes: a stacked structural unit including a plurality of insulating films alternately stacked with a plurality of electrode films in a first direction; a selection gate electrode stacked on the stacked structural unit in the first direction; an insulating layer stacked on the selection gate electrode in the first direction; a first semiconductor pillar piercing the stacked structural unit, the selection gate electrode, and the insulating layer in the first direction, a first cross section of the first semiconductor pillar having an annular configuration, the first cross section being cut in a plane orthogonal to the first direction; a first core unit buried in an inner side of the first semiconductor pillar, the first core unit being recessed from an upper face of the insulating layer; and a first conducting layer of the first semiconductor pillar provided on the first core unit to contact the first core unit.

A three-dimensional memory device includes an alternating stack of electrically conductive layers and insulating layers located over a substrate, an array of memory stack structures. An alternating sequence of support pedestal structures and conductive rail structures extending along a same horizontal direction are provided between the substrate and the alternating stack. Each memory stack structure straddles a vertical interface between a conductive rail structure and a support pedestal structure. A semiconductor channel in each memory stack structure contacts a respective conductive rail structure, and is electrically isolated from an adjacent support pedestal structure by a portion of a memory film. The conductive rail structures can function as source regions of memory device.

A flash memory structure includes a memory gate on a substrate, a select gate adjacent to the memory gate, and an oxide-nitride spacer between the memory gate and the select gate, where the oxide-nitride spacer further includes an oxide layer and a nitride layer having an upper nitride portion and a lower nitride portion, and the upper nitride portion is thinner than the lower nitride portion.

Integrated circuits and methods of forming the same are provided. An exemplary integrated circuit includes a semiconductor substrate having a central shallow trench isolation (STI) region. A pair of select transistors have drain regions in contact with opposite portions of the central STI region. A central gate structure overlies the central STI region and includes a central gate dielectric layer. The central gate dielectric layer has a medial dielectric region overlying the central STI region, a first lateral dielectric region overlying the first drain region, and a second lateral dielectric region overlying the second drain region. The first lateral dielectric region defines a first programmable element and the second lateral dielectric region defines a second programmable element.

The present disclosure relates to a structure and method for embedding a non-volatile memory (NVM) in a HKMG (high- metal gate) integrated circuit which includes a high voltage (HV) HKMG transistor. NVM devices (e.g., flash memory) are operated at high voltages for its read and write operations and hence a HV device is necessary for integrated circuits involving non-volatile embedded memory and HKMG logic circuits. Forming a HV HKMG circuit along with the HKMG periphery circuit reduces the need for additional boundaries between the HV transistor and rest of the periphery circuit. This method further helps reduce divot issue and reduce cell size.