Abstract: A method for forming a capacitor of a semiconductor device includes the steps of forming first and second sacrificial insulation layers over a semiconductor substrate divided into first and second regions. The second and first sacrificial insulation layers in the first region are etched to define in the first region of the semiconductor substrate. Storage nodes on surfaces of the holes are formed. A partial thickness of the second sacrificial insulation layer is etched to partially expose upper portions of the storage nodes. A mask pattern is formed to cover the first region while exposing the second sacrificial insulation layer remaining in the second region. The exposed second sacrificial insulation layer in the second region is removed to expose the first sacrificial insulation layer in the second region. The exposed first sacrificial insulation layer in the second region and the first sacrificial insulation layer in the first region is removed. The mask pattern is removed.

Abstract: A method for fabricating a capacitor in a semiconductor device includes: forming a bottom electrode; forming a ZrxAlyOz dielectric layer on the bottom electrode using an atomic layer deposition (ALD) method, wherein the ZrxAlyOz dielectric layer comprises a zirconium (Zr) component, an aluminum (Al) component and an oxygen (O) component mixed in predetermined mole fractions of x, y and z, respectively; and forming a top electrode on the ZrxAlyOz dielectric layer.

Abstract: The present invention relates to an electrode 100 with high capacitance. The electrode includes a conducting substrate 10 with a number of nano-sized structures 13 thereon and a coating 15. The nano-sized structures are concave-shaped and are of a size in the range from 2 nanometers to 50 nanometers. The nano-sized structures are configured for increasing specific surface area of the electrode. The present invention also provides a method for making the above-described electrode. The method includes steps of providing a conducting substrate, forming a number of nano-sized structures on the conducting substrate, and forming a coating on the nano-sized structures.

Abstract: Provided are a semiconductor device and a method of fabricating the same. The semiconductor device includes an insulating layer that is formed on a supporting layer and has a contact hole. A first contact plug is formed on an inner wall and bottom of the contact hole. A second contact plug buries the contact hole and is formed on the first contact plug. A conductive layer is connected to the first contact plug and the second contact plug. The bottom thickness of the first contact plug formed on the bottom of the contact hole is thicker than the inner wall thickness of the first contact plug formed on the inner wall of the contact hole.

Abstract: The semiconductor memory device includes: an interlayer insulating film that is formed on a semiconductor substrate; an insulating film that is formed on the interlayer insulating film and has a cylinder hole; and a capacitor that has an impurity-containing silicon film, a lower metal electrode, a capacitive insulating film and an upper electrode, which are formed so as to cover a bottom and a side of the cylinder hole, wherein the cylinder hole extends through the insulating film so as to expose an end side of the contact plug, the end side facing opposite from the source electrode; and the impurity-containing silicon film has a silicide layer near an interface between the impurity-containing silicon film and the lower metal electrode, the silicide layer being produced by a reaction of impurity-containing silicon included in the impurity-containing silicon film with metal included in the lower metal electrode.

Abstract: A method for forming a capacitor comprises providing a substrate. A bottom electrode material layer is formed on the substrate. A first mask layer is formed on the bottom electrode material layer. A second mask layer is formed on the first mask layer. The second mask layer is patterned to form a patterned second mask layer in a predetermined region for formation of a capacitor. A plurality of hemispherical grain structures are formed on a sidewall of the patterned second mask layer. The first mask layer is etched by using the hemispherical grain structures and the patterned second mask layer as a mask, thereby forming a patterned first mask layer having a pattern. The pattern of the first mask layer is transferred to the bottom electrode material layer. And, a capacitor dielectric layer and a top electrode layer are formed on the bottom electrode material layer to form the capacitor.

Abstract: A method for fabricating a semiconductor device is disclosed. The semiconductor device includes a capacitor and a support insulator. The capacitor includes a cylindrical electrode. The cylindrical electrode comprises upper and lower sections. The lower section has a roughened inner surface and an outer surface supported by the support insulator. The upper section upwardly projects from the support insulator. An initial cylindrical electrode is formed, wherein the initial cylindrical electrode comprises an initial upper section and an initial lower section which correspond to the upper section and the lower section of the cylindrical electrode, respectively. The initial upper section is supported by the support insulator. Specific impurities are implanted into the initial upper section, wherein the specific impurities serve to prevent the initial upper section from being roughened.

Abstract: In order to form a storage electrode of a semiconductor memory device, an interlayer dielectric layer is formed on a semiconductor substrate having a bit line thereon. A contact hole exposing the semiconductor substrate is formed by patterning the interlayer dielectric layer. A polysilicon layer is etched to a predetermined thickness using polysilicon etching gas after the polysilicon layer is deposited. An over-etch process is performed relative to the polysilicon layer, and then a storage node contact having a planarized surface is formed in the contact hole by performing an etching process for planarizing the surface of the polysilicon layer. A mold insulating layer is formed on the resultant structure, in which the mold insulating layer exposes an area where the storage node contact is formed. A storage electrode coupled to the storage node contact is formed.

Abstract: A method for fabricating a storage node contact in a semiconductor device includes forming a landing plug over a substrate, forming a first insulation layer over the landing plug, forming a bit line pattern over the first insulation layer, forming a second insulation layer over the bit line pattern, forming a mask pattern for forming a storage node contact over the second insulation layer, etching the second and first insulation layers until the landing plug is exposed to form a storage node contact hole including a portion having a rounded profile, filling a conductive material in the storage node contact hole to form a contact plug, and forming a storage node over the contact plug.

Abstract: According to an aspect of the invention, there is provided a semiconductor device including a plurality of memory cells, comprising a plurality of floating gate electrodes which are formed on a tunnel insulating film formed on a semiconductor substrate and have an upper portion which is narrower in a channel width direction than a lower portion, an interelectrode insulating film formed on the floating gate electrodes, and a control gate electrode which is formed on the interelectrode insulating film formed on the floating gate electrodes and partially buried between the floating gate electrodes opposing each other.

Abstract: A method of fabricating an MIM type capacitor includes at least one of: Forming a first trench within an insulating interlayer formed on a semiconductor substrate. Forming a lower electrode layer of a metal nitride layer substance to fill an inside of the first trench. Forming a second trench on a surface of the lower electrode layer to have a depth less than the first trench. Forming a capacitor dielectric layer conformal along a surface of the lower electrode layer including the second trench. Forming an upper electrode layer of a metal nitride layer substance on the capacitor dielectric layer. Sequentially patterning the upper electrode layer and the capacitor dielectric layer by photolithography.

Abstract: A method of fabricating a uniformly wrinkled capacitor lower electrode without the need to perform a high-temperature heat treatment and a method of fabricating a capacitor including the uniformly wrinkled capacitor lower electrode are provided. A first conductive layer is formed. Then, a second conductive layer including about 20% to about 50% of impurities is formed on the first conductive layer. Next, at least some of the impurities are exhausted from the second conductive layer by heat treating the second conductive layer. A surface of the second conductive layer is wrinkled due to the exhaustion of the impurities from the second conductive layer. A dielectric layer and an upper capacitor electrode may then be formed.

Abstract: A semiconductor capacitor structure comprising sidewalls of conductive hemispherical grained material, a base of metal silicide material, and a metal nitride material overlying the conductive hemispherical grained material and the metal silicide material. The semiconductor capacitor structure is fabricated by forming a base of metal silicide material along the sidewalls of an insulative material having an opening therein, forming sidewalls of conductive hemispherical grained material on the metal silicide material, and forming a metal nitride material overlying the conductive hemispherical grained material and the metal silicide material.

Abstract: A dynamic random access memory device including a capacitor structure, e.g., trench, stack. The device includes a substrate (e.g., silicon, silicon on insulator, epitaxial silicon) having a surface region. The device includes an interlayer dielectric region overlying the surface region. In a preferred embodiment, the interlayer dielectric region has an upper surface and a lower surface. The device has a container structure within a portion of the interlayer dielectric region. The container structure extends from the upper surface to the lower surface. The container structure has a first width at the upper surface and a second width at the lower surface. The container structure has an inner region extending from the upper surface to the lower surface. In a specific embodiment, the container structure has a higher dopant concentration within a portion of the inner region within a vicinity of the lower surface and on a portion of the inner region near the vicinity of the lower surface.

Abstract: The present invention relates to a method for fabricating a capacitor of a semiconductor device. The method includes the steps of: forming a first amorphous silicon layer doped with an impurity in a predetermined first doping concentration suppressing dopants from locally agglomerating; forming an impurity undoped second amorphous silicon layer on the first amorphous silicon layer in an in-situ condition; forming a storage node by patterning the first amorphous silicon layer and the second amorphous silicon layer; forming silicon grains on a surface of the storage node; and doping the impurity to the storage node and the silicon grains until reaching a second predetermined concentration for providing conductivity required by the storage node.

Abstract: A method for selectively removing nano-crystals on an insulating layer. The method includes providing an insulating layer with nano-crystals thereon; exposing the nano-crystals to a high density plasma comprising a source of free radical chlorine, ionic chlorine, or both to modify the nano-crystals; and removing the modified nano-crystals with a wet etchant.

Abstract: A method for fabricating a semiconductor device, the method includes forming an etch stop layer and an insulation layer over a substrate having a first region and a second region, selectively removing the insulation layer and the etch stop layer in the first region to expose parts of the substrate, thereby forming at least two electrode regions on the exposed substrate and a resultant structure, forming a conductive layer over the resultant structure, removing the conductive layer in the second region, removing the insulation layer in the first region and the second region by using wet chemicals, and removing parts of the conductive layer, which formed between the at least two electrode regions in the first region, to form cylinder type electrodes in the first region.

Abstract: Methods for forming the lower electrode of a capacitor in a semiconductor circuit, and the capacitors formed by such methods are provided. The lower electrode is fabricated by forming a texturizing underlayer and then depositing a conductive material thereover. In one embodiment of a method of forming the lower electrode, the texturizing layer is formed by depositing a polymeric material comprising a hydrocarbon block and a silicon-containing block, over the insulative layer of a container, and then subsequently converting the polymeric film to relief or porous nanostructures by exposure to UV radiation and ozone, resulting in a textured porous or relief silicon oxycarbide film. A conductive material is then deposited over the texturizing layer resulting in a lower electrode have an upper roughened surface.

Abstract: A method of manufacturing a nonvolatile memory device includes forming a plurality of device isolation regions in a semiconductor substrate, forming a tunneling insulation layer on the semiconductor substrate, forming a first preliminary polysilicon layer in communication with the tunneling insulation layer and the device isolation regions, forming a preliminary amorphous silicon layer on the first preliminary silicon layer, forming a second preliminary polysilicon layer on the preliminary amorphous silicon layer, and patterning the second preliminary polysilicon layer, the preliminary amorphous silicon layer, and the first preliminary polysilicon layer to form a floating gate layer.

Abstract: The present invention provides a manufacturing method for an integrated semiconductor structure comprising the steps of providing a semiconductor substrate having a plurality of gate stacks in a memory cell region and at least one gate stack in a peripheral device region; forming caps made of one or more layers of a cap material over said plurality of gate stacks in said memory cell region and over said at least one gate stack in said peripheral device region; depositing a first protective layer made of carbon or made of a carbon containing material over said memory cell region and peripheral device region; forming a mask layer on said first protective layer in said memory cell region; exposing said cap of said at least one gate stack in said peripheral device region by removing said first protective layer in said peripheral device region in an etch step wherein said mask layer acts as a mask in said memory cell region; removing said mask layer and said first protective layer from said memory cell region; for

Abstract: An integrated circuit arrangement and fabrication method is presented. The integrated circuit arrangement contains a semiconductor and a metal electrode. The contact area between a semiconductor and the electrode is increased without increasing the lateral dimensions using partial regions of the semiconductor and/or of the electrode that extend through a transition layer between the semiconductor and electrode.

Abstract: A method of fabricating an integrated circuit capacitor includes forming a first metal layer on a conductive plug in an interlayer insulating layer on a substrate. At least a portion of the first metal layer is silicided to form a metal silicide layer and a remaining first metal layer on the conductive plug. The remaining first metal layer is removed using a dry etching process. A lower electrode including a second metal layer is then formed on the metal silicide layer. Because the remaining first metal layer is removed, etching and/or other damage to the conductive plug and/or the interlayer insulating layer during a subsequent wet ethching process may be reduced and/or prevented.

Abstract: A semiconductor capacitor structure comprising sidewalls of conductive hemispherical grained material, a base of metal silicide material, and a metal nitride material overlying the conductive hemispherical grained material and the metal silicide material. The semiconductor capacitor structure is fabricated by forming a base of metal silicide material along the sidewalls of an insulative material having an opening therein, forming sidewalls of conductive hemispherical grained material on the metal silicide material, and forming a metal nitride material overlying the conductive hemispherical grained material and the metal silicide material.

Abstract: A DRAM stack capacitor and a fabrication method thereof has a first capacitor electrode formed of a conductive carbon layer overlying a semiconductor substrate, a capacitor dielectric layer and a second capacitor electrode. The first capacitor electrode is of crown shape geometry and possesses an inner surface and an outer surface. The DRAM stack capacitor features the outer surface of the first capacitor electrode as an uneven surface.

Abstract: A semiconductor structure and a method for fabricating the semiconductor structure include at least one field effect transistor, and also a capacitor, located over a substrate. In particular, the capacitor is located interposed between the field effect transistor and the substrate. The field effect transistor may include a planar field effect transistor as well as a fin-FET. The capacitor may be connected with a conductor plug layer to a source/drain region of the field effect transistor to form a dynamic random access memory cell structure.

Abstract: The invention includes methods of forming pluralities of capacitors. In one implementation, a method of forming a plurality of capacitors includes anodically etching individual capacitor electrode channels within a material over individual capacitor storage node locations on a substrate. The channels are at least partially filled with electrically conductive capacitor electrode material in electrical connection with the individual capacitor storage node locations. The capacitor electrode material is incorporated into a plurality of capacitors. Other aspects and implementations are contemplated.

Abstract: A phase change memory device and a method of fabricating the same are disclosed. The phase change memory device includes a first conductor pattern having a first conductivity type and a sidewall. A second conductor pattern is connected to the sidewall of the first conductor pattern to form a diode. A phase change layer is electrically connected to the second conductor pattern and a top electrode is connected to the phase change layer.

Abstract: A stressed field effect transistor and methods for its fabrication are provided. The field effect transistor comprises a silicon substrate with a gate insulator overlying the silicon substrate. A gate electrode overlies the gate insulator and defines a channel region in the silicon substrate underlying the gate electrode. A first silicon germanium region having a first thickness is embedded in the silicon substrate and contacts the channel region. A second silicon germanium region having a second thickness greater than the first thickness and spaced apart from the channel region is also embedded in the silicon substrate.

Abstract: The invention relates to a method of forming a memory device comprising a memory cell array and a peripheral portion. When forming the capacitors in the memory cell array, a sacrificial layer is deposited which is usually made of silicon dioxide and which is used for defining the storage electrode above the substrate surface. The sacrificial layer is removed selectively from the array portion while being maintained in the peripheral portion. This is achieved by providing an array separation trench which acts as a lateral etch stop.

Abstract: A method of manufacturing dynamic random access memory (DRAM) cylindrical capacitor is provided. A substrate having a polysilicon plug formed therein is provided. A dielectric layer having an opening is disposed on the substrate, wherein the opening exposes the polysilicon plug. Thereafter, an amorphous silicon spacer is formed on the sidewall of the opening to expose a portion of the polysilicon plug. Next, a top portion of the exposed polysilicon plug is removed and a seeding method is used to grow a hemispherical silicon grain (HSG) layer on a surface of the amorphous silicon spacer. A capacitor dielectric layer is formed on the surface of the HSG layer and a conductive layer is then formed on the capacitor dielectric layer. As no HSG is formed on the polysilicon plug, and therefore the contact area of the capacitor is not decreased.

Abstract: Some embodiments include methods of forming metal-containing oxides. The methods may utilize ALD where a substrate surface is exposed to an organometallic composition while the substrate surface is at a temperature of at least 275° C. to form a metal-containing layer. The metal-containing layer may then be exposed to at least one oxidizing agent to convert the metal-containing layer to a metal-containing oxide. The ALD may occur in a reaction chamber, with the oxidizing agent and the organometallic composition being present within such chamber at substantially non-overlapping times relative to one another. The oxidizing agent may be a milder oxidizing agent than ozone. The metal-containing oxide may be utilized as a capacitor dielectric, and may be incorporated into a DRAM unit cell.

Abstract: A method for forming a capacitor comprises providing a substrate. A bottom electrode material layer is formed on the substrate. A first mask layer is formed on the bottom electrode material layer. A second mask layer is formed on the first mask layer. The second mask layer is patterned to form a patterned second mask layer in a predetermined region for formation of a capacitor. A plurality of hemispherical grain structures are formed on a sidewall of the patterned second mask layer. The first mask layer is etched by using the hemispherical grain structures and the patterned second mask layer as a mask, thereby forming a patterned first mask layer having a pattern. The pattern of the first mask layer is transferred to the bottom electrode material layer. And, a capacitor dielectric layer and a top electrode layer are formed on the bottom electrode material layer to form the capacitor.

Abstract: A polysilicon film is formed with enhanced selectivity by flowing chlorine during the formation of the film. The chlorine acts as an etchant to insulative areas adjacent polysilicon structures on which the film is desired to be formed. Bottom electrodes for capacitors are formed using this process, followed by an anneal to create hemishperical grain (HSG) polysilicon. Multilayer capacitor containers are formed in a non-oxidizing ambient so that no oxide is formed between the layers. The structure formed is planarized to form separate containers made from doped and undoped amorphous silicon layers. Selected ones of undoped layers are seeded in a chlorine containing environment and annealed to form HSG. A dielectric layer and second electrode are formed to complete the cell capacitor.

Abstract: The present invention relates to semiconductor devices, preferably dynamic random access memory (DRAM) cells, each of which contains at least one trench capacitor with a buried isolation collar. The trench capacitor is located in a trench in a semiconductor substrate, and it comprises inner and outer electrodes and a dielectric layer. The buried isolation collar is recessed into a sidewall of the trench and has a substantially uniform thickness. Such a buried isolation collar is preferably formed by oxygen implantation before trench etching.

Abstract: The invention includes methods of forming rugged electrically conductive surfaces. In one method, a layer is formed across a substrate and subsequently at least partially dissociated to form gaps extending to the substrate. An electrically conductive surface is formed to extend across the at least partially dissociated layer and within the gaps. The electrically conductive surface has a rugged topography imparted by the at least partially dissociated layer and the gaps. The topographically rugged surface can be incorporated into capacitor constructions. The capacitor constructions can be incorporated into DRAM cells, and such DRAM cells can be incorporated into electrical systems.

Abstract: A capacitor is provided including a storage node contact pad and a storage electrode. The storage electrode includes at least two cylindrical conductive patterns. The at least two cylindrical conductive patterns are electrically coupled to a portion of a surface of the storage node contact pad. Related methods are also provided.

Abstract: The present invention relates to a method for fabricating a capacitor of a semiconductor device. The method includes the steps of: forming a first amorphous silicon layer doped with an impurity in a predetermined first doping concentration suppressing dopants from locally agglomerating; forming an impurity undoped second amorphous silicon layer on the first amorphous silicon layer in an in-situ condition; forming a storage node by patterning the first amorphous silicon layer and the second amorphous silicon layer; forming silicon grains on a surface of the storage node; and doping the impurity to the storage node and the silicon grains until reaching a second predetermined concentration for providing conductivity required by the storage node.

Abstract: A method for forming a capacitor comprises providing a substrate. A bottom electrode material layer is formed on the substrate. A first mask layer is formed on the bottom electrode material layer. A second mask layer is formed on the first mask layer. The second mask layer is patterned to form a patterned second mask layer in a predetermined region for formation of a capacitor. A plurality of hemispherical grain structures are formed on a sidewall of the patterned second mask layer. The first mask layer is etched by using the hemispherical grain structures and the patterned second mask layer as a mask, thereby forming a patterned first mask layer having a pattern. The pattern of the first mask layer is transferred to the bottom electrode material layer. And, a capacitor dielectric layer and a top electrode layer are formed on the bottom electrode material layer to form the capacitor.

Abstract: In a semiconductor device having a capacitor and a method of fabricating the same, the semiconductor device comprises a semiconductor substrate and an insulating layer on the semiconductor substrate, a contact plug electrically connected to the semiconductor substrate and formed in the contact hole, a buffer conductive layer pattern electrically connected to the contact plug and formed on the insulating layer and the contact plug, an etching stopping layer formed on the buffer conductive layer pattern, a gap between the buffer conductive layer pattern and the etching stopping layer, a capacitor lower electrode electrically connected to the buffer conductive layer pattern and formed on the buffer conductive layer pattern. The gap is filled by a portion of the capacitor lower electrode.

Abstract: The present invention relates to a capacitor in semiconductor device and a method of manufacturing the same, wherein, owing to formation of a lower electrode and an upper electrode into a stack structure of a poly-silicon layer and an aluminum (Al) layer and formation of an alumina (Al2O3) film as a dielectric film, the lower electrode is formed into a stack structure of the poly-silicon layer-aluminum (Al) layer, thus increasing a surface area of electrodes due to the absence of oxidation during annealing, and preventing degeneration of the device, and use of the dielectric film including a high-dielectric constant material layer enables reduction of the dielectric film's thickness. Accordingly, the present invention is capable of increasing capacitance, is capable of reducing leakage current and improving dielectric breakdown characteristics via internal formation of an MIM capacitor, and is capable of reducing production costs by performing a continuous process via use of a single piece of equipment.

Abstract: Methods are provided for robust and cost effective techniques to fabricate a semiconductor device having double-sided hemispherical silicon grain (HSG) electrodes for container capacitors. In an embodiment, this is accomplished by forming a layer of hemispherical silicon grain (HSG) polysilicon over interior surfaces of a polysilicon layer of a container formed in a substrate. An oxide cap may be formed on the top portion of the container.

Abstract: The present invention provides a manufacturing method for an integrated semiconductor structure comprising the steps of: providing a semiconductor substrate having a plurality of gate stacks in a memory cell region and at least one gate stack in a peripheral device region; forming caps made of one or more layers of a cap material over said plurality of gate stacks in said memory cell region and over said at least one gate stack in said peripheral device region; forming a first contact hole between two neighboring gate stacks in said memory cell region; depositing a first protective layer over said memory cell region and peripheral device region; exposing said cap of said at least one gate stack in said peripheral device region; modifying said exposed cap of said at least one gate stack in said peripheral device region in a process step wherein said first protective layer acts as a mask in said memory cell region; forming a second protective layer over said modified cap in said peripheral device region; partly

Abstract: The capacitor in a semiconductor device includes a substrate, a lower electrode formed over the substrate, a diffusion barrier formed over the lower electrode, a plurality of agglomerates formed over the diffusion barrier, a dielectric layer formed over the surface of the agglomerates to form an uneven surface, and an upper electrode formed over the dielectric layer.

Abstract: A method for fabricating a semiconductor device includes forming a first trench by etching a substrate already provided with a storage node contact (SNC) region and a bit line contact (BLC) region, forming a protection layer on sidewalls of the first trench, forming a sacrificial layer over the substrate and filling the first trench, etching the sacrificial layer to have a portion of the sacrificial layer remain in the first trench in the BLC region of the substrate, forming a second trench extending horizontally by etching the substrate underneath the first trench, and filling the first and second trenches to form an isolation structure.

Abstract: A method for forming storage node contacts in a semiconductor device includes forming an interlayer dielectric layer on a semiconductor substrate provided with transistors; forming a hydrogen diffusion preventing layer on the interlayer dielectric layer; forming a hard mask layer containing hydrogen atoms on the hydrogen diffusion preventing layer; forming storage node contact holes, which pass through the hydrogen diffusion preventing layer and the interlayer dielectric layer and expose impurity regions of the transistors, by etching the hydrogen diffusion preventing layer and the interlayer dielectric layer using the hard mask layer as an etching barrier layer; and forming the storage node contacts by filling the storage node contact holes with a conductive layer.

Abstract: Methods for etching metal nitrides and metal oxides include using ultradilute HF solutions and buffered, low-pH HF solutions containing a minimal amount of the hydrofluoric acid species H2F2. The etchant can be used to selectively remove metal nitride layers relative to doped or undoped oxides, tungsten, polysilicon, and titanium nitride. A method is provided for producing an isolated capacitor, which can be used in a dynamic random access memory cell array, on a substrate using sacrificial layers selectively removed to expose outer surfaces of the bottom electrode.

Abstract: A nitride layer of the gate mask for the semiconductor device is deposited at a temperature higher than 750 deg. C so as to release hydrogen from the nitride layer. Alternatively, a nitride layer of the gate mask for the semiconductor device is deposited in a gas atmosphere with use of an ammonia gas and a silane gas such that a flow rate of the ammonia gas is set at least twenty times or greater than that of the silane gas. Accordingly, the problem with respect to the threshold voltages Vt of the semiconductor devices varying greatly from device to device when the polysilicon layer or the amorphous silicon layer is formed in the vicinity of the nitride layer and is doped with Group III impurities, will be solved.

Abstract: In a capacitor of a semiconductor device, a bottom electrode is formed on a substrate and has an uneven top surface. An interlayer insulation layer is formed on the substrate and has a via hole exposing the top surface of the bottom electrode. A dielectric layer is formed unevenly on the bottom electrode. A top electrode is formed on the dielectric layer while filling the via hole.

Abstract: The invention includes methods of forming rugged electrically conductive surfaces. In one method, a layer is formed across a substrate and subsequently at least partially dissociated to form gaps extending to the substrate. An electrically conductive surface is formed to extend across the at least partially dissociated layer and within the gaps. The electrically conductive surface has a rugged topography imparted by the at least partially dissociated layer and the gaps. The topographically rugged surface can be incorporated into capacitor constructions. The capacitor constructions can be incorporated into DRAM cells, and such DRAM cells can be incorporated into electrical systems.

Abstract: The invention includes methods of electrochemically treating semiconductor substrates. The invention includes a method of electroplating a substance. A substrate having defined first and second regions is provided. The first and second regions can be defined by a single mask, and accordingly can be considered to be self-aligned relative to one another. A first electrically conductive material is formed over the first region, and a second electrically conductive material is formed over the second region. The first and second electrically conductive materials are exposed to an electrolytic solution while providing electrical current to the first and second electrically conductive materials. A desired substance is selectively electroplated onto the first electrically conductive material during the exposing of the first and second electrically conductive materials to the electrolytic solution. The invention also includes methods of forming capacitor constructions.