Abstract: A method for manufacturing a shallow trench isolation structure comprises etching a plurality of trenches into a silicon substrate. The trenches have an upright wall portion, a bottom floor portion, and a corner portion connecting the upright wall portion and the bottom floor portion. The method further comprises conformally depositing a dielectric layer into the trenches. The dielectric layer covers at least part of the upright wall portion, at least part of the bottom floor portion, and at least part of the corner portion. The method further comprises oxidizing the dielectric layer. A portion of the dielectric layer deposited over the corner portion is oxidized at a first oxidization rate, and a portion of the dielectric layer deposited over the upright wall portion is oxidized at a second oxidization rate. The first oxidization rate is less than the second oxidization rate. The method further comprises depositing an electrically insulating material into the trenches over the dielectric layer.

Abstract: A structure and a method of fabricating a bottom electrode of a metal-insulator-metal (MIM) capacitor are provided. First, a transition metal layer is formed on a substrate. Thereafter, a self-assembling polymer film having a nano-pattern is formed on the transition metal layer to expose a portion of the transition metal layer. Using the self-assembling polymer film as a mask, the exposed portion of the transition metal layer is treated to undergo a phase change so that the bottom electrode can achieve a nano-level of phase separation. Thereafter, the self-assembling polymer film is removed.

Abstract: The invention relates to integrated circuit fabrication, and more particularly to an electronic device with an isolation structure made having almost no void. An exemplary method for fabricating an isolation structure, comprising: providing a substrate; forming a trench in the substrate; partially filling the trench with a first silicon oxide; exposing a surface of the first silicon oxide to a vapor mixture comprising NH3 and a fluorine-containing compound; heating the substrate to a temperature between 100° C. to 200° C.; and filling the trench with a second silicon oxide, whereby the isolation structure made has almost no void.

Abstract: A bilayer porous low dielectric constant (low-k) interconnect structure and methods of fabricating the same are presented. A preferred embodiment having an effective dielectric constant of about 2.2 comprises a bottom deposited dielectric layer and a top deposited dielectric layer in direct contact with the former. The bottom layer and the top layer have same atomic compositions, but a higher dielectric constant value k. The bottom dielectric layer serves as an etch stop layer for the top dielectric layer, and the top dielectric layer can act as CMP stop layer. One embodiment of making the structure includes forming a bottom dielectric layer having a first porogen content and a top dielectric layer having a higher porogen content. A curing process leaves lower pore density in the bottom dielectric layer than that left in the top dielectric layer, which leads to higher dielectric value k in the bottom dielectric layer.

Abstract: A nanocrystal memory element and a method for fabricating the same are proposed. The fabricating method involves selectively oxidizing polysilicon not disposed beneath and not covered with a plurality of metal nanocrystals, and leaving intact the polysilicon disposed beneath and thereby covered with the plurality of metal nanocrystals, with a view to forming double layered silicon-metal nanocrystals by self-alignment.

Abstract: An interlayer interconnect structure of a three-dimensional memory includes memory cell groups, each composed of a plurality of memory cells and connected to their respective selection transistors, because of special arrangement of lines and first plugs as well as line layouts. The line layouts involve disposing a plurality of lines on each of a plurality of horizontal levels, and selectively forming second plugs between adjoining lines disposed on upper and lower horizontal levels, such that the plugs selectively connect the adjoining upper and lower lines to each other. Since identical layout patterns are adopted in individual stacking states of stacking layers disposed in the three-dimensional memory, the upper lines and the lower lines of the stacking layers of the three-dimensional memory share the same layouts, leading to a reduction in the number of masks used, simpler process adjustment, and lower costs.

Abstract: A nanocrystal memory element and a method for fabricating the same are proposed. The fabricating method involves selectively oxidizing polysilicon not disposed beneath and not covered with a plurality of metal nanocrystals, and leaving intact the polysilicon disposed beneath and thereby covered with the plurality of metal nanocrystals, with a view to forming double layered silicon-metal nanocrystals by self-alignment.

Abstract: A bilayer porous low dielectric constant (low-k) interconnect structure and methods of fabricating the same are presented. A preferred embodiment having an effective dielectric constant of about 2.2 comprises a bottom deposited dielectric layer and a top deposited dielectric layer in direct contact with the former. The bottom layer and the top layer have same atomic compositions, but a higher dielectric constant value k. The bottom dielectric layer serves as an etch stop layer for the top dielectric layer, and the top dielectric layer can act as CMP stop layer. One embodiment of making the structure includes forming a bottom dielectric layer having a first porogen content and a top dielectric layer having a higher porogen content. A curing process leaves lower pore density in the bottom dielectric layer than that left in the top dielectric layer, which leads to higher dielectric value k in the bottom dielectric layer.

Abstract: A nanocrystal memory element and a method for fabricating the same are proposed. The fabricating method involves selectively oxidizing polysilicon not disposed beneath and not covered with a plurality of metal nanocrystals, and leaving intact the polysilicon disposed beneath and thereby covered with the plurality of metal nanocrystals, with a view to forming double layered silicon-metal nanocrystals by self-alignment.

Abstract: An interlayer interconnect structure of a three-dimensional memory includes memory cell groups, each composed of a plurality of memory cells and connected to their respective selection transistors, because of special arrangement of lines and first plugs as well as line layouts. The line layouts involve disposing a plurality of lines on each of a plurality of horizontal levels, and selectively forming second plugs between adjoining lines disposed on upper and lower horizontal levels, such that the plugs selectively connect the adjoining upper and lower lines to each other. Since identical layout patterns are adopted in individual stacking states of stacking layers disposed in the three-dimensional memory, the upper lines and the lower lines of the stacking layers of the three-dimensional memory share the same layouts, leading to a reduction in the number of masks used, simpler process adjustment, and lower costs.

Abstract: A structure and a method of fabricating a bottom electrode of a metal-insulator-metal (MIM) capacitor are provided. First, a transition metal layer is formed on a substrate. Thereafter, a self-assembling polymer film having a nano-pattern is formed on the transition metal layer to expose a portion of the transition metal layer. Using the self-assembling polymer film as a mask, the exposed portion of the transition metal layer is treated to undergo a phase change so that the bottom electrode can achieve a nano-level of phase separation. Thereafter, the self-assembling polymer film is removed.

Abstract: A vertically-stacked three-dimensional nanocrystal memory device and a method for manufacturing the same is proposed. Each of the two vertically overlapping memory cells of the vertically-stacked three-dimensional nanocrystal memory device includes a thin-film transistor and nanocrystals embedded in a gate dielectric layer of the thin-film transistor. With the two vertically overlapping memory cells including, sharing and being controlled by a wordline, the bit density of the memory increases.

Abstract: A resistance-change nanocrystal memory is proposed, which includes at least one memory unit. The memory unit further includes a channel and nanocrystals embedded in the channel. Electric charges in the nanocrystals are accessed, by applying a voltage to the channel. Then, conductivity of the channel is altered by the electric charges stored in the nanocrystals. Eventually, electric current is measured while an additional transistor is on, so as to achieve memory functions.

Abstract: A nanocrystal memory element and a method for fabricating the same involves repeatedly and alternately depositing, by atomic layer deposition, conductive layers and dielectric layers on a substrate with a tunnel oxide layer formed thereon, forming multiple layers of nanocrystal groups as a result of crystallization of conductive layers in a rapid thermal annealing process, and forming a gate on the top dielectric layer. The nanocrystal groups disposed at any two neighboring levels are separated by one dielectric layer, thus a plurality of nanocrystals formed in an integration layer are disposed at the same level. Barrier widths between a channel and the nanocrystals of the nanocrystal groups disposed at the same level are equal. Therefore, the nanocrystals at the same level are subjected the same electric field when voltage is applied to the gate, resulting in improved transistor performance, enhanced control of threshold voltage, and avoidance of over-erasing.

Abstract: A nanocrystal memory element and a method for fabricating the same are proposed. The fabricating method involves selectively oxidizing polysilicon not disposed beneath and not covered with a plurality of metal nanocrystals, and leaving intact the polysilicon disposed beneath and thereby covered with the plurality of metal nanocrystals, with a view to forming double layered silicon-metal nanocrystals by self-alignment.

Abstract: A memory device with an improved passivation structure. The memory device includes a semiconductor substrate with memory units thereon, an interconnect structure over the surface of the semiconductor substrate to connect with the memory units, and a passivation structure over the surface of the interconnect structure. The passivation structure comprises a dielectric layer over the surface of the interconnect structure and a silicon-oxy-nitride (SiOxNy) layer over the surface of the dielectric layer.

Abstract: A method of improving flash memory performance. The method includes: providing a substrate having a gate structure thereon, the gate structure having a gate dielectric layer, a first polysilicon layer, an interploy dielectric layer, and a second polysilicon layer; then, depositing an gate insulating layer to enclose the gate structure, for forming side wall spacers; next, performing a first anneal on the substrate and the enclosed gate structure; then, performing a cell reoxidation on the substrate and the enclosed gate structure by dilute oxidation process using mixed gas comprising oxygen O2 and nitrogen N2. The invention reduces encroachment issues in the interpoly dielectric layer and the tunnel oxide and improves gate coupling ratio (GCR).

Abstract: A method for manufacturing a shallow trench isolation structure comprises etching a plurality of trenches into a silicon substrate. The trenches have an upright wall portion, a bottom floor portion, and a corner portion connecting the upright wall portion and the bottom floor portion. The method further comprises conformally depositing a dielectric layer into the trenches. The dielectric layer covers at least part of the upright wall portion, at least part of the bottom floor portion, and at least part of the corner portion. The method further comprises oxidizing the dielectric layer. A portion of the dielectric layer deposited over the corner portion is oxidized at a first oxidization rate, and a portion of the dielectric layer deposited over the upright wall portion is oxidized at a second oxidization rate. The first oxidization rate is less than the second oxidization rate. The method further comprises depositing an electrically insulating material into the trenches over the dielectric layer.

Abstract: A method of improving flash memory performance. The method includes: providing a substrate having a gate structure thereon, the gate structure having a gate dielectric layer, a first polysilicon layer, an interploy dielectric layer, and a second polysilicon layer; then, depositing an gate insulating layer to enclose the gate structure, for forming side wall spacers; next, performing a first anneal on the substrate and the enclosed gate structure; then, performing a cell reoxidation on the substrate and the enclosed gate structure by dilute oxidation process using mixed gas comprising oxygen O2 and nitrogen N2. The invention reduces encroachment issues in the interpoly dielectric layer and the tunnel oxide and improves gate coupling ratio (GCR).

Abstract: In a manufacturing method for a shallow trench isolation, first, a multi-layer structure is formed over a semiconductor substrate. A first trench is formed in the multi-layer structure to define an isolation region and an active region. Sidewalls in the first trench are formed by depositing sidewall material over the multi-layer structure and surfaces of the first trench and etching the sidewall material. An isolation trench is then formed in the substrate by etching the substrate using the sidewalls and the multi-layer structure as a mask. Then the sidewalls are etched back to expose a portion of the substrate surface. Thermal oxidation is performed to oxidize the second trench, wherein the etched sidewalls and the multi-layer structure protect the substrate underneath from being oxidized. Then, the oxidized second trench is filled with a filling material and the whole structure is polished. The amount by which the sidewalls are etched back controls a bird beak that is formed in the active region.