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 method of forming a split gate memory cell structure using a substrate includes forming a gate stack comprising a select gate and a dielectric portion overlying the select gate. A charge storage layer is formed over the substrate including over the gate stack. A first sidewall spacer of conductive material is formed along a first sidewall of the gate stack extending past a top of the select gate. A second sidewall spacer of dielectric material is formed along the first sidewall on the first sidewall spacer. A portion of the first sidewall spacer is silicided using the second sidewall spacer as a mask whereby silicide does not extend to the charge storage 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 memory, including: a first memory cell including a first transistor; a second memory cell including a second transistor; and a memory peripherals transistor, the memory peripherals transistor is overlaying the second transistor or is underneath the first transistor, where the second memory cell overlays the first memory cell at a distance of less than 200 nm, and where the memory peripherals transistor is part of a peripherals circuit controlling the memory.

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 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.

A non-volatile memory cell, and method of making, that includes a semiconductor substrate having a fin shaped upper surface with a top surface and two side surfaces. Source and drain regions are formed in the fin shaped upper surface portion with a channel region there between. A conductive floating gate includes a first portion extending along a first portion of the top surface, and second and third portions extending along first portions of the two side surfaces, respectively. A conductive control gate includes a first portion extending along a second portion of the top surface, second and third portions extending along second portions of the two side surfaces respectively, a fourth portion extending up and over at least some of the floating gate first portion, and fifth and sixth portions extending out and over at least some of the floating gate second and third portions respectively.

An irreproducible and re-emergent unique structure or pattern identifier manufacturing and detection method, system, and apparatus is provided. A non-volatile floating gate charge storage device can include a block of floating gate transistors that can include a semiconductor region, a source region, a drain region, a floating gate region, a tunnel oxide region, an oxide-nitrite-oxide region, and a control gate region. A structure altering stress effect is applied to the block of transistors to create a passage region in a random number of floating gate regions of floating gate transistors which changes charge storage or electrical characteristics of random elements of the block of transistors. The passage region alters charges on a floating gate region to escape in a different manner than pre-alteration form causing the floating gate region to lose its charge. An apparatus for recording and detecting such differences in pre and post alteration can also be provided.

A method of forming a semiconductor structure of a control gate is provided, including depositing a first dielectric layer overlying a substrate, forming a surface modification layer from the first dielectric layer; and forming semiconductor dots on the surface modification layer. The surface modification layer has a bonding energy to the semiconductor dots less than the bonding energy between the first dielectric layer and the semiconductor dots. Therefore the semiconductor dots have higher density to form on the surface modification layer than that to directly form on the first dielectric layer. And a semiconductor device is also provided to tighten threshold voltage (Vt) and increase programming efficiency.

Methods of fabricating a memory cell of a semiconductor device, e.g., an EEPROM cell, having a sidewall oxide are disclosed. A memory cell structure may be formed including a floating gate and an ONO film over the conductive layer. A sidewall oxide may be formed on a side surface of the floating gate by a process including depositing a thin high temperature oxide (HTO) film on the side surface of the conductive layer, and performing a rapid thermal oxidation (RTO) anneal. The thin HTO film may be deposited before or after performing the RTO anneal. The sidewall oxide formation process may provide an improved memory cell as compared with known prior art techniques, e.g., in terms of endurance and data retention.