Abstract: Structures and formation methods of a semiconductor device structure are provided. The semiconductor device structure includes a substrate. The substrate includes a first semiconductor layer, a second semiconductor layer, and an insulating layer between the first semiconductor layer and the second semiconductor layer. The semiconductor device structure also includes a gate stack over the substrate. The semiconductor device structure further includes source and drain structures in the second semiconductor layer of the substrate. The source and drain structures are on opposite sides of the gate stack. In addition, the semiconductor device structure includes a first isolation feature in the substrate. The first isolation feature includes an insulation material and surrounds the source and drain structures. The semiconductor device structure also includes a second isolation feature in the first isolation feature. The second isolation feature includes a metal material and surrounds the source and drain structures.

Abstract: A high-voltage metal capacitor with easy integration into existing semiconductor manufacturing processes can provide isolation capacitors up to several kilovolts. The capacitor includes a support layer with internal structure, including a lower place, a bond pad on the support layer, an upper plate disposed on the support layer, the upper plate being arranged above the lower plate, a dielectric layer, at least part of which is between the lower and upper plates, and a passivation layer, at least part of which covers at least part of the upper plate and part of the dielectric layer. A first opening extends from the surface through the passivation and dielectric layers to the lower plate, and a second opening extends from the surface through the passivation layer to the upper plate. A method of manufacturing the capacitor.

Abstract: A structure forming a metal-insulator-metal (MIM) trench capacitor is disclosed. The structure comprises a multi-layer substrate having a metal layer and at least one dielectric layer. A trench is etched into the substrate, passing through the metal layer. The trench is lined with a metal material that is in contact with the metal layer, which comprises a first node of a capacitor. A dielectric material lines the metal material in the trench. The trench is filled with a conductor. The dielectric material that lines the metal material separates the conductor from the metal layer and the metal material lining the trench. The conductor comprises a second node of the capacitor.

Abstract: A structure and method is provided for fabricating isolated capacitors. The method includes simultaneously forming a plurality of deep trenches and one or more isolation trenches surrounding a group or array of the plurality of deep trenches through a SOI and doped poly layer, to an underlying insulator layer. The method further includes lining the plurality of deep trenches and one or more isolation trenches with an insulator material. The method further includes filling the plurality of deep trenches and one or more isolation trenches with a conductive material on the insulator material. The deep trenches form deep trench capacitors and the one or more isolation trenches form one or more isolation plates that isolate at least one group or array of the deep trench capacitors from another group or array of the deep trench capacitors.

Abstract: A method of fabricating a semiconductor memory device includes forming a hard mask pattern using a damascene method on a lower mold layer stacked on a substrate and etching the lower mold layer using the hard mask pattern as an etch mask to define a protrusion under the hard mask pattern. A support pattern is formed on a top surface of the etched lower mold layer, the top surface of the etched lower mold layer being located at a lower level than a top surface of the protrusion. A lower electrode supported by the support pattern is formed.

Abstract: A finFET trench circuit is disclosed. FinFETs are integrated with trench capacitors by employing a trench top oxide over a portion of the trench conductor. A passing gate is then disposed over the trench top oxide to form a larger circuit, such as a DRAM array. The trench top oxide is formed by utilizing different growth rates between polysilicon and single crystal silicon.

Abstract: A semiconductor device comprises a trench isolation. The trench isolation is formed in a surface of a semiconductor substrate to define an active region a well region, and a bottom of the trench isolation is positioned within the well region. The trench isolation includes a conductive wiring electrically connected to the well region and an insulating film which buries the conductive wiring in the bottom of the trench isolation. Semiconductor elements are disposed in the active region.

Abstract: An oven comprising a controller that operates the oven in a food cooking mode and in energy saving mode in which energy consumption of a heater and one or more fans is reduced. In the food cooking mode the controller maintains heated air flow at a first set temperature. In the energy saving mode the controller maintains the heated air flow at a second set temperature, which is less than the first set temperature, thereby reducing energy consumed by the heater. In the energy mode, controller also operates the fan that circulates the heater air and a cooling fan at reduced speeds, thereby reducing energy consumption of both fans.

Abstract: A method of filling shallow trenches is disclosed. The method includes: successively forming a first oxide layer and a second oxide layer over the surface of a silicon substrate where shallow trenches are formed in; etching the second oxide layer to form inner sidewalls with an etchant which has a high etching selectivity ratio of the second oxide layer to the first oxide layer; growing a high-quality pad oxide layer by thermal oxidation after the inner sidewalls are removed; and filling the trenches with an isolation dielectric material. By using this method, the risk of occurrence of junction spiking and electrical leakage during a subsequent process of forming a metal silicide can be reduced.

Abstract: A method for formation of a shallow trench isolation (STI) in an active region of a device comprising trench capacitive elements, the trench capacitive elements comprising a metal plate and a high-k dielectric includes etching a STI trench in the active region of the device, wherein the STI trench is directly adjacent to at least one of the metal plate or high-k dielectric of the trench capacitive elements; and forming an oxide liner in the STI trench, wherein the oxide liner is formed selectively to the metal plate or high-k dielectric, wherein forming the oxide liner is performed at a temperature of about 600° C. or less.

Abstract: A structure and method is provided for fabricating isolated capacitors. The method includes simultaneously forming a plurality of deep trenches and one or more isolation trenches surrounding a group or array of the plurality of deep trenches through a SOI and doped poly layer, to an underlying insulator layer. The method further includes lining the plurality of deep trenches and one or more isolation trenches with an insulator material. The method further includes filling the plurality of deep trenches and one or more isolation trenches with a conductive material on the insulator material. The deep trenches form deep trench capacitors and the one or more isolation trenches form one or more isolation plates that isolate at least one group or array of the deep trench capacitors from another group or array of the deep trench capacitors.

Abstract: A structure and method is provided for fabricating isolated capacitors. The method includes simultaneously forming a plurality of deep trenches and one or more isolation trenches surrounding a group or array of the plurality of deep trenches through a SOI and doped poly layer, to an underlying insulator layer. The method further includes lining the plurality of deep trenches and one or more isolation trenches with an insulator material. The method further includes filling the plurality of deep trenches and one or more isolation trenches with a conductive material on the insulator material. The deep trenches form deep trench capacitors and the one or more isolation trenches form one or more isolation plates that isolate at least one group or array of the deep trench capacitors from another group or array of the deep trench capacitors.

Abstract: A method of forming a trench structure that includes forming a metal containing layer on at least the sidewalls of a trench, and forming an undoped semiconductor fill material within the trench. The undoped semiconductor fill material and the metal containing layer are recessed to a first depth within the trench with a first etch. The undoped semiconductor fill material is then recessed to a second depth within the trench that is greater than a first depth with a second etch. The second etch exposes at least a sidewall portion of the metal containing layer. The trench is filled with a doped semiconductor containing material fill, wherein the doped semiconductor material fill is in direct contact with the at least the sidewall portion of the metal containing layer.

Abstract: A semiconductor component includes a semiconductor body, in which are formed: a substrate of a first conduction type, a buried semiconductor layer of a second conduction type arranged on the substrate, and a functional unit semiconductor layer of a third conduction type arranged on the buried semiconductor layer, in which at least two semiconductor functional units arranged laterally alongside one another are provided. The buried semiconductor layer is part of at least one semiconductor functional unit, the semiconductor functional units being electrically insulated from one another by an isolation structure which permeates the functional unit semiconductor layer, the buried semiconductor layer, and the substrate. The isolation structure includes at least one trench and an electrically conductive contact to the substrate, the contact to the substrate being electrically insulated from the functional unit semiconductor layer and the buried layer by the at least one trench.

Abstract: A method for manufacturing a semiconductor device is disclosed. The method includes forming a shallow trench isolation (STI) region extending in a first direction on a semiconductor substrate, forming a mask layer extending in a second direction that intersects with the first direction on the semiconductor substrate and forming a trench on the semiconductor substrate by using the STI region and the mask layer as masks. In addition, the method includes forming a charge storage layer so as to cover the trench and forming a conductive layer on side surfaces of the trench and the mask layer. Word lines are formed from the conductive layer on side surfaces of the trench that oppose in the first direction by etching. The word lines are separated from each other and extend in the second direction.

Abstract: A semiconductor process is provided. A mask layer is formed on a substrate and has a first opening exposing a portion of the substrate. Using the mask layer as a mask, a dry etching process is performed on the substrate to form a second opening therein. The second opening has a bottom portion and a side wall extending upwards and outwards from the bottom portion, wherein the bottom portion is exposed by the first opening and the side wall is covered by the mask layer. Using the mask layer as a mask, a vertical ion implantation process is performed on the bottom portion. A conversion process is performed, so as to form converting layers on the side wall and the bottom portion of the second opening, wherein a thickness of the converting layer on the side wall is larger than a thickness of the converting layer on the bottom portion.

Abstract: Disclosed is an integrated circuit having at least one deep trench isolation structure and a deep trench capacitor. A method of forming the integrated circuit incorporates a single etch process to simultaneously form first trench(s) and a second trenches for the deep trench isolation structure(s) and a deep trench capacitor, respectively. Following formation of a buried capacitor plate adjacent to the lower portion of the second trench, the trenches are lined with a conformal insulator layer and filled with a conductive material. Thus, for the deep trench capacitor, the conformal insulator layer functions as the capacitor dielectric and the conductive material as a capacitor plate in addition to the buried capacitor plate. A shallow trench isolation (STI) structure formed in the substrate extending across the top of the first trench(es) encapsulates the conductive material therein, thereby creating the deep trench isolation structure(s).

Abstract: A semiconductor device, including a semiconductor substrate including isolations defining active regions of the semiconductor substrate, and a plurality of buried gate electrodes between a pair of the isolations, wherein each of the buried gate electrodes and the isolations includes a conductive layer and a capping layer.

Abstract: Dopants of a first conductivity type are implanted into a top portion of a semiconductor substrate having a doping of the first conductivity type to increase the dopant concentration in the top portion, which is a first-conductivity-type semiconductor layer. A semiconductor material layer having a doping of the second conductivity type, a buried insulator layer, and a top semiconductor layer are formed thereupon. Deep trenches having a narrow width have a bottom surface within the second-conductivity-type semiconductor layer, which functions as a buried plate. Deep trenches having a wider width are etched into the first-conductivity-type layer underneath, and can be used to form an isolation structure. The additional dopants in the first-conductivity-type semiconductor layer provide a counterdoping against downward diffusion of dopants of the second conductivity type to enhance electrical isolation.

Abstract: A method for forming a semiconductor structure includes forming an isolation region in a semiconductor substrate; forming a conductive layer over the isolation region; forming a first dielectric layer over the conductive layer; forming a plurality of conductive vias extending through the first dielectric layer to the conductive layer and electrically contacting the conductive layer; forming a second dielectric layer over the first dielectric layer; and forming a conductive ground plane in the second dielectric layer. Each of the plurality of conductive vias is in electrical contact with the conductive ground plane, and the conductive ground plane includes an opening, wherein the opening is located directly over the conductive layer. At least one interconnect layer may be formed over the second dielectric layer and may include a transmission line which transmits a signal having a frequency of at least 30 gigahertz.

Abstract: A semiconductor device includes transistors with a vertical gate electrode. In a transistor structure, a semiconductor pattern has first and second sides facing in a transverse direction, and third and fourth sides facing in a longitudinal direction. Gate patterns are disposed adjacent to the first and second sides of the semiconductor pattern. Impurity patterns directly contact the third and fourth sides of the semiconductor pattern. A gate insulating pattern is interposed between the gate patterns and the semiconductor pattern.

Abstract: A method for improving conformality of oxide layers along sidewalls of vias in semiconductor substrates includes forming a nitride layer over an upper surface of a semiconductor substrate and forming a via extending through the nitride layer and into the semiconductor substrate. The via may have a depth of at least about 50 ?m from a top surface of the nitride layer and an opening of less than about 10 ?m at the top surface of the nitride layer. The method also includes forming an oxide layer over the nitride layer and along sidewalls and bottom of the via. The oxide layer may be formed using a thermal chemical vapor deposition (CVD) process at a temperature of less than about 450° C., where a thickness of the oxide layer at the bottom of the via is at least about 50% of a thickness of the oxide layer at the top surface of the nitride layer.

Abstract: A semiconductor structure having U-shaped transistors includes source/drain regions at the tops of pairs of pillars defined by crossing trenches in the substrate. One pillar is connected to the other pillar in the pair by a ridge that extends above the surrounding trenches. The ridge and lower portions of the pillars define U-shaped channels on opposite sides of the U-shaped structure, facing a gate structure in the trenches on those opposite sides, forming a two sided surround transistor. Optionally, the space between the pillars of a pair is also filled with gate electrode material to define a three-sided surround gate transistor. One of the source/drain regions of each pair extending to a digit line and the other extending to a memory storage device, such as a capacitor. Methods of forming semiconductor structures are also disclosed.

Abstract: A method is provided that includes forming a trench isolation structure in a dynamic random memory region (DRAM) of a substrate and patterning an etch mask over the trench structure to expose a portion of the trench structure. A portion of the exposed trench structure is removed to form a gate trench that includes a first corner formed by the substrate and a second corner formed by the trench structure. The etch mask is removed and the first corner of the gate trench is rounded to form a rounded corner. This is followed by the formation of an oxide layer over a sidewall of the gate trench, the first rounded corner, and the semiconductor substrate adjacent the gate trench. The trench is filled with a gate material.

Abstract: A method of manufacturing a capacitor of a semiconductor device includes forming a high-k dielectric pattern on a semiconductor substrate, the high-k dielectric pattern having a pillar shape including a hole therein, forming a lower electrode in the hole of the high-k dielectric pattern, locally forming a blocking insulating pattern on an upper surface of the lower electrode, and forming an upper electrode covering the high-k dielectric pattern and the blocking insulating pattern.

Abstract: An isolation structure comprising a substrate is provided. A trench is in the substrate. A sidewall of the trench has a first inclined surface and a second inclined surface. The first inclined surface is located on the second inclined surface. The slope of the first inclined surface is different from the slope of the second inclined surface. A length of the first inclined surface is greater than 15 nanometers.

Abstract: A structure and method for forming isolation and a buried plate for a trench capacitor is disclosed. Embodiments of the structure comprise an epitaxial layer serving as the buried plate, and a bounded deep trench isolation area serving to isolate one or more deep trench structures. Embodiments of the method comprise angular implanting of the deep trench isolation area to form a P region at the base of the deep trench isolation area that serves as an anti-punch through implant.

Abstract: Provided is a semiconductor capacitor including: a capacitor device forming region having a trapezoidal trench which is formed on a surface of a first conductivity type semiconductor substrate; a second conductivity type lower electrode layer provided along the trapezoidal trenches of the capacitor device forming region; a capacitor insulating film formed at least on a surface of the second conductivity type lower electrode layer; and a second conductivity type upper electrode formed on a surface of the capacitor insulating film.

Abstract: A method of forming a capacitor structure includes forming a pad oxide layer overlying a substrate, a nitride layer overlying the pad oxide layer, an interlayer dielectric layer overlying the nitride layer, and a patterned polysilicon mask layer overlying the interlayer dielectric layer. The method then applies a first RIE process to form a trench region through a portion of the interlayer dielectric layer using the patterned polysilicon mask layer and maintaining the first RIE to etch through a portion of the nitride layer and through a portion of the pad oxide layer. The method stops the first RIE when a portion of the substrate has been exposed. The method then forms an oxide layer overlying the exposed portion of the substrate and applies a second RIE process to continue to form the trench region by removing the oxide layer and removing a portion of the substrate to a predetermined depth.

Abstract: An SOI device includes an SOI substrate having a stacked structure including a buried oxide layer and a first silicon layer sequentially stacked on a silicon substrate. The SOI substrate possesses grooves having a depth that extends from an upper surface of the first silicon layer to a partial depth of the buried oxide layer. An insulation layer is formed on the lower surfaces of the grooves and a second silicon layer is formed filling the grooves having the insulation layer formed thereon. Gates are formed on the second silicon layer and junction regions are formed in the first silicon layer on both sides of the gates to contact the insulation layer.

Abstract: In a method of designing a mask layout, a wiring region for forming a metal wire is established, the wiring region having at least a standard width. Contact regions for forming contacts electrically connected to the metal wire are established in the wiring region. The contact regions adjacent to each other are grouped to divide the wiring region into a first region and a second region including the contact regions. First dummy regions are established in the first region, the first dummy regions corresponding to regions for forming first dummy patterns. Second dummy regions are established among the contact regions in the second region, the second dummy regions corresponding to regions for forming second dummy patterns.

Abstract: A method for fabricating a semiconductor device includes forming a plurality of active regions that are separated from each other by a plurality of trenches, respectively, wherein the trenches are formed by etching a substrate, forming an insulation layer having openings that each expose a portion of a first sidewall of each active region, forming a filling layer which fills the openings, forming a diffusion control layer over a substrate structure including the filling layer, and forming a junction on a portion of the first sidewall of each active region.

Abstract: Disclosed is an integrated circuit having at least one deep trench isolation structure and a deep trench capacitor. A method of forming the integrated circuit incorporates a single etch process to simultaneously form first trench(s) and a second trenches for the deep trench isolation structure(s) and a deep trench capacitor, respectively. Following formation of a buried capacitor plate adjacent to the lower portion of the second trench, the trenches are lined with a conformal insulator layer and filled with a conductive material. Thus, for the deep trench capacitor, the conformal insulator layer functions as the capacitor dielectric and the conductive material as a capacitor plate in addition to the buried capacitor plate. A shallow trench isolation (STI) structure formed in the substrate extending across the top of the first trench(es) encapsulates the conductive material therein, thereby creating the deep trench isolation structure(s).

Abstract: A capacitor is described which includes a substrate with a doped area of the substrate forming a first electrode of the capacitor. A plurality of trenches is arranged in the doped area of the substrate, the plurality of trenches forming a second electrode of the capacitor. An electrically insulating layer is arranged between each of the plurality of trenches and the doped area for electrically insulating the trenches from the doped area. The doped area includes first open areas and at least one second open area arranged between neighboring trenches of the plurality of trenches, wherein the at least one open area is arranged below the at least one substrate contact. A shortest first distance between neighboring trenches is separated by the first open areas and is shorter than a shortest second distance between neighboring trenches separated by the at least one second open area.

Abstract: An isolation structure comprising a substrate is provided. A trench is in the substrate. A sidewall of the trench has a first inclined surface and a second inclined surface. The first inclined surface is located on the second inclined surface. The slope of the first inclined surface is different from the slope of the second inclined surface. A length of the first inclined surface is greater than 15 nanometers.

Abstract: According to yet another embodiment, a method for forming a non-volatile memory device includes etching a substrate to form first and second trenches. The first and second trenches are filled with an insulating material to form first and second isolation structures. A conductive layer is formed over the first and second isolation structures and between the first and second isolation structures to form a floating gate. The conductive layer and the first isolation structure are etched to form a third trench having an upper portion and a lower portion, the upper portion having vertical sidewalls and the lower portion having sloping sidewalls. The third trench is filled with a conductive material to form a control gate.

Abstract: Semiconductor devices with an improved overlay margin and methods of manufacturing the same are provided. In one aspect, a method includes forming a buried bit line in a substrate; forming an isolation layer in the substrate to define an active region, the isolation layer being parallel to the bit line without overlapping the bit line; and forming a gate line including a gate pattern and a conductive line by forming the gate pattern in the active region and forming a conductive line that extends at a right angle to the bit line across the active region and is electrically connected to the gate pattern disposed thereunder. The gate pattern and the conductive line can be integrally formed.

Abstract: A structure and method for forming isolation and a buried plate for a trench capacitor is disclosed. Embodiments of the structure comprise an epitaxial layer serving as the buried plate, and a bounded deep trench isolation area serving to isolate one or more deep trench structures. Embodiments of the method comprise angular implanting of the deep trench isolation area to form a P region at the base of the deep trench isolation area that serves as an anti-punch through implant.

Abstract: A semiconductor component includes a semiconductor body, in which are formed: a substrate of a first conduction type, a buried semiconductor layer of a second conduction type arranged on the substrate, and a functional unit semiconductor layer of a third conduction type arranged on the buried semiconductor layer, in which at least two semiconductor functional units arranged laterally alongside one another are provided. The buried semiconductor layer is part of at least one semiconductor functional unit, the semiconductor functional units being electrically insulated from one another by an isolation structure which permeates the functional unit semiconductor layer, the buried semiconductor layer, and the substrate. The isolation structure includes at least one trench and an electrically conductive contact to the substrate, the contact to the substrate being electrically insulated from the functional unit semiconductor layer and the buried layer by the at least one trench.

Abstract: A semiconductor device including at least one drift region formed near a channel region on a substrate, a first buried insulating layer formed in the drift region, and a first reduced surface field region interposed between the first buried insulating layer and the drift region. Accordingly, the semiconductor device provides first reduced surface field regions arranged between drift regions and first buried insulating layers, thus having advantages of improved junction integrity, suitability for LDMOS transistors employing a high operation voltage and reduced total size.

Abstract: Method of manufacturing a non-volatile memory device on a semiconductor substrate in a memory area, said non-volatile memory device comprising a cell stack of a first semiconductor layer, a charge trapping layer and an electrically conductive layer, the charge trapping layer being the intermediate layer between the first semiconductor layer and the electrically conductive layer, the charge trapping layer comprising at least a first insulating layer; the method comprising: —providing the substrate having the first semiconductor layer; —depositing the charge trapping layer; —depositing the electrically conductive layer; —patterning the cell stack to form at least two non-volatile memory cells, and —creating a shallow trench isolation in between said at least two non-volatile memory cells.

Abstract: A semiconductor device includes a first insulating layer, a capacitor, an adhesive layer, and an intermediate layer. The first insulating layer may include a first insulating film. The first insulating layered structure has a first hole. The capacitor is disposed in the first hole. The capacitor may include bottom and top electrodes and a capacitive insulating film. The capacitive insulating film is sandwiched between the bottom and top electrodes. The adhesive layer contacts with the bottom electrode. The adhesive layer has adhesiveness to the bottom electrode. The intermediate layer is interposed between the adhesive layer and the first insulating film. The intermediate layer contacts with the adhesive layer and with the first insulating film. The intermediate layer has adhesiveness to the adhesive layer and to the first insulating film.

Abstract: Roughly described, methods and systems for improving integrated circuit layouts and fabrication processes in order to better account for stress effects. Dummy features can be added to a layout either in order to improve uniformity, or to relax known undesirable stress, or to introduce known desirable stress. The dummy features can include dummy diffusion regions added to relax stress, and dummy trenches added either to relax or enhance stress. A trench can relax stress by filling it with a stress-neutral material or a tensile strained material. A trench can increase stress by filling it with a compressive strained material. Preferably dummy diffusion regions and stress relaxation trenches are disposed longitudinally to at least the channel regions of N-channel transistors, and transversely to at least the channel regions of both N-channel and P-channel transistors. Preferably stress enhancement trenches are disposed longitudinally to at least the channel regions of P-channel transistors.

Abstract: A method of manufacturing a dual contact trench capacitor is provided. The method includes forming a first plate provided within a trench and isolated from a wafer body by a first insulator layer formed in the trench. The method further includes forming a second plate provided within the trench and isolated from the wafer body and the first plate by a second insulator layer formed in the trench.

Abstract: A dielectric interlayer, especially for a storage capacitor, is formed from a layer sequence subjected to a temperature process, wherein the layer sequence has at least a first metal oxide layer and a second metal oxide layer formed by completely oxidizing a metal nitride layer to higher valency.

Abstract: A semiconductor device and methods for its fabrication are provided. The semiconductor device comprises a trench formed in the semiconductor substrate and bounded by a trench wall extending from the semiconductor surface to a trench bottom. A drain region and a source region, spaced apart along the length of the trench, are formed along the trench wall, each extending from the surface toward the bottom. A channel region is formed in the substrate along the trench wall between the drain region and the source region and extending along the length of the trench parallel to the substrate surface. A gate insulator and a gate electrode are formed overlying the channel.

Abstract: A deep trench (DT) capacitor comprises a trench in a silicon layer, a buried plate surrounding the trench, a dielectric layer lining the trench, and a node conductor in the trench. The top surface of the poly node is higher than the surface of the silicon layer, so that it is high enough to ensure that a nitride liner used as a CMP etch stop for STI oxide surrounding a top portion of the poly node will be higher than the STI oxide, so that the nitride liner can be removed prior to forming a silicide contact on top of the poly node.

Abstract: A method for manufacturing a semiconductor device that controls the influence of a thickness of a stopper film even if there is a change in the thickness of the stopper film by measuring the thickness prior to etching to a predetermined thickness.

Abstract: A semiconductor structure including a trench formed in a substrate and a buried isolation collar that extends about sidewalls of the trench. The buried isolation collar is constituted by an insulator formed from a buried porous region of substrate material. The porous region is formed from a buried doped region defined using masking and ion implantation or by masking the trench sidewalls and using dopant diffusion. Advantageously, the porous region is transformed to an oxide insulator by an oxidation process. The semiconductor structure may be a storage capacitor of a memory cell further having a buried plate about the trench and a capacitor node inside the trench that is separated from the buried plate by a node dielectric formed on the trench sidewalls.

Abstract: One embodiment of the present invention relates to a method of forming an isolation structure. During this method, an isolation trench is formed within a semiconductor body. After this trench is formed, it is filled by performing multiple high-frequency plasma depositions to deposit multiple dielectric layers over the semiconductor body. A first of the multiple layers is deposited at a high-frequency power of between approximately 100 watts and approximately 900 watts.