Abstract: A method of forming circuitry components includes forming a stack of horizontally extending and vertically overlapping features. The stack has a primary portion and an end portion. At least some of the features extend farther in the horizontal direction in the end portion moving deeper into the stack in the end portion. Operative structures are formed vertically through the features in the primary portion and dummy structures are formed vertically through the features in the end portion. Horizontally elongated openings are formed through the features to form horizontally elongated and vertically overlapping lines from material of the features. The lines individually extend from the primary portion into the end portion, and individually laterally about sides of vertically extending portions of both the operative structures and the dummy structures.

Abstract: In a substrate wiring method, copper is embedded all the way to the lowest parts of a wiring pattern formed on a substrate. The method is used to wire a substrate in a processing chamber kept in a vacuum state, the substrate having a wiring pattern formed thereon. The method includes a preprocessing step in which the wiring pattern on the substrate is cleaned using a desired cleaning gas and an embedding step in which, after the preprocessing step, metal nanoparticles are embedded in the wiring pattern using a clustered metal gas.

Abstract: A method of forming overlapping contacts in a semiconductor device includes forming a first contact in a dielectric layer; etching the dielectric layer to form a recess adjacent to the first contact and removing a top portion of the first contact while etching the dielectric layer, wherein a bottom portion of the first contact remains in the dielectric layer after the recess is formed in the dielectric layer; and forming a second contact in the recess adjacent to the bottom portion of the first contact and on top of a top surface of the bottom portion of the first contact.

Abstract: Methods of fabricating components for microelectronic devices are described herein. For example, one embodiment is directed toward a method of fabricating a memory cell on a workpiece having a substrate, a plurality of active areas in the substrate, and a dielectric layer over the active areas. Bit line contact openings can be formed in the dielectric layer over first portions of the active areas and cell plug openings over second portions of the active areas. A first conductive material is deposited into the bit line contact openings to form bit line contacts and into the cell plug openings to form cell plugs. A conductive line is formed in a trench in the substrate. Dielectric features can electrically insulate the conductive line.

Abstract: An integrated circuit structure includes a substrate, a metal ring penetrating through the substrate, a dielectric region encircled by the metal ring, and a through-via penetrating through the dielectric region. The dielectric region is in contact with the through-via and the metal ring.

Abstract: A semiconductor structure and a fabricating process for the same are provided. The semiconductor fabricating process includes providing a first dielectric layer, a transitional layer formed on the first dielectric layer, and a conductive fill penetrated through the transitional layer and into the first dielectric layer; removing the transitional layer; and forming a second dielectric layer over the conductive fill and the first dielectric layer.

Abstract: Among other things, one or more support structures and techniques for forming such support structures within semiconductor devices are provided. The support structure comprises an oxide infused silicon layer that is formed within a trench of a dielectric layer on a substrate of a semiconductor device. The oxide infused silicon layer results from a silicon layer that is exposed to oxide during an ultraviolet (UV) curing process. The oxide infused silicon layer is configured to support a barrier layer against a conductive structure formed on the barrier layer within the trench. In this way, the support structure provides pressure against the barrier layer so that the barrier layer substantially maintains contact with the conductive structure, to promote improved performance and reliability of the conductive structure.

Abstract: A method of forming a through substrate interconnect includes forming a via into a semiconductor substrate. The via extends into semiconductive material of the substrate. A liquid dielectric is applied to line at least an elevationally outermost portion of sidewalls of the via relative a side of the substrate from which the via was initially formed. The liquid dielectric is solidified within the via. Conductive material is formed within the via over the solidified dielectric and a through substrate interconnect is formed with the conductive material.

Abstract: A high programming efficiency electrical fuse is provided utilizing a dual damascene structure located atop a metal layer. The dual damascene structure includes a patterned dielectric material having a line opening located above and connected to an underlying via opening. The via opening is located atop and is connected to the metal layer. The dual damascene structure also includes a conductive feature within the line opening and the via opening. Dielectric spacers are also present within the line opening and the via opening. The dielectric spacers are present on vertical sidewalls of the patterned dielectric material and separate the conductive feature from the patterned dielectric material. The presence of the dielectric spacers within the line opening and the via opening reduces the area in which the conductive feature is formed. As such, a high programming efficiency electrical fuse is provided in which space is saved.

Abstract: According to one embodiment, a semiconductor device includes a lower layer connection object, a stacked body, an insulating film, and a via. The stacked body has a plurality of insulating layers and a plurality of electrode layers alternately stacked on the lower layer connection object. The stacked body has a staircase structure unit. The via connects uppermost electrode layer at each step of the staircase structure unit and the lower layer connection object through the via hole. The via has an upper part provided on and in contact with a top face of the uppermost electrode layer, and a penetrating part provided to be thinner than the upper part inside the insulating film in the via hole. The penetrating part connects the upper part and the lower layer connection object.

Abstract: In accordance with an embodiment, a structure comprises a substrate having a first area and a second area; a through substrate via (TSV) in the substrate penetrating the first area of the substrate; an isolation layer over the second area of the substrate, the isolation layer having a recess; and a conductive material in the recess of the isolation layer, the isolation layer being disposed between the conductive material and the substrate in the recess.

Abstract: A method of fabricating a semiconductor integrated circuit (IC) is disclosed. The method includes providing a substrate. A first dielectric layer is deposited on the substrate. A patterned photoresist layer is formed on the first dielectric layer. The patterned photoresist layer is trimmed. The first dielectric layer is etched through the trimmed patterned photoresist layer to form a dielectric feature. A sacrificing energy decomposable layer (SEDL) is deposited on the dielectric feature and etched to form a SEDL spacer on sides of the dielectric feature. A second dielectric layer is deposited on the SEDL spacer and etched to form a dielectric spacer. The SEDL spacer is decomposed to form a trench.

Abstract: A method for forming a device is disclosed. A substrate having first and second major surfaces is provided. A stress buffer is formed in the substrate. A through silicon via (TSV) contact is formed between the stress buffer. The stress buffer has a depth less than a depth of the TSV contact. The stress buffer alleviates stress created by the difference in coefficient thermal expansion (CTE) between the TSV contact and the substrate.

Abstract: Through the intermetal dielectric (2) and the semiconductor material of the substrate (1) a contact hole is formed, and a contact area of a connection metal plane (3) that faces the substrate is exposed in the contact hole. A metallization (11) is applied, which forms a connection contact (12) on the contact area, a through-contact (13) in the contact hole and a connection contact (20) on a contact area facing away from the substrate and/or on a vertical conductive connection (15) of the upper metal plane (24).

Abstract: Semiconductor devices and methods of manufacture thereof are disclosed. In one embodiment, a method of manufacturing a semiconductor device includes providing a workpiece including an insulating material layer disposed thereon. The insulating material layer includes a trench formed therein. The method includes forming a barrier layer on the sidewalls of the trench using a surface modification process and a surface treatment process.

Abstract: A method for double patterning is disclosed. In one embodiment the formation a pair of select gate wordlines on either side of a plurality of core wordlines begins by placing a spacer pattern around edges of a photoresist pattern is disclosed. The photoresist pattern is stripped away leaving the spacer pattern. A trim mask is placed over a portion of the spacer pattern. Portions of the spacer pattern are etched away that are not covered by the trim mask. The trim mask is removed, wherein first remaining portions of the spacer pattern define a plurality of core wordlines. A pad mask is placed such that the pad mask and second remaining portions of the spacer pattern define a select gate wordline on either side of the plurality of core wordlines. Finally at least one pattern transfer layer is etched through using the mad mask and the first and second remaining portions of the spacer pattern to etch the select gate wordlines and the plurality of core wordlines into a poly silicon layer.

Abstract: A differential port and a method of arranging the differential port are described. The method includes arranging a first electrode to receive a drive signal, and arranging a second electrode to receive a guard signal, the guard signal having a different phase than the drive signal and the first electrode and the second electrode having a gap therebetween. The method also includes disposing a signal line from the first electrode to drive a radio frequency (RF) device.

Abstract: Embodiments of the present invention provide a contact structure for transistor. The contact structure includes a first epitaxial-grown region between a first and a second gate of, respectively, a first and a second transistor; a second epitaxial-grown region directly on top of the first epitaxial-grown region with the second epitaxial-grown region having a width that is wider than that of the first epitaxial-grown region; and a silicide region formed on a top portion of the second epitaxial-grown region with the silicide region having an interface, with rest of the second epitaxial-grown region, that is wider than that of the first epitaxial-grown region. In one embodiment, the second epitaxial-grown region is at a level above a top surface of the first and second gates of the first and second transistors.

Abstract: Methods of forming conductive elements on and in a substrate include forming a layer of conductive material over a surface of a substrate prior to forming a plurality of vias through the substrate from an opposing surface of the substrate to the layer of conductive material. In some embodiments, a temporary carrier may be secured to the layer of conductive material on a side thereof opposite the substrate prior to forming the vias. Structures, including workpieces formed using such methods, are also disclosed.

Abstract: An integrated circuit (IC) including a set of isolated wire structures disposed within a layer of the IC, methods of manufacturing the same and design structures are disclosed. The method includes forming adjacent wiring structures on a same level, with a space therebetween. The method further includes forming a capping layer over the adjacent wiring structures on the same level, including on a surface of a material between the adjacent wiring structures. The method further includes forming a photosensitive material over the capping layer. The method further includes forming an opening in the photosensitive material between the adjacent wiring structures to expose the capping layer. The method further includes removing the exposed capping layer.

Abstract: A method of forming stacked die devices includes attaching first semiconductor die onto a wafer to form a reconstituted wafer, and then bonding second semiconductor die onto the first semiconductor die to form a plurality of singulated stacked die devices on the wafer. A support tape is attached to a bottomside of the second semiconductor die. A dicing tape is attached to the wafer. The wafer is laser irradiated before or after attachment of the dicing tape at intended dicing lanes that align with gaps between the first semiconductor die to mechanically weaken the wafer at the intended dicing lanes, but not cut through the wafer. The dicing tape is pulled to cleave the wafer into a plurality of singulated portions to form a plurality of singulated stacked die devices attached to the singulated wafer portions by the dicing tape. The support tape is removed prior to cleaving.

Abstract: A method of fabricating a substrate includes forming spaced first features over a substrate. An alterable material is deposited over the spaced first features and the alterable material is altered with material from the spaced first features to form altered material on sidewalls of the spaced first features. A first material is deposited over the altered material, and is of some different composition from that of the altered material. The first material is etched to expose the altered material and spaced second features comprising the first material are formed on sidewalls of the altered material. Then, the altered material is etched from between the spaced second features and the spaced first features. The substrate is processed through a mask pattern comprising the spaced first features and the spaced second features. Other embodiments are disclosed.

Abstract: A method of providing signal, power and ground through a through-silicon-via (TSV), and an integrated circuit chip having a TSV that simultaneously provides signal, power and ground. In one embodiment, the method comprises forming a TSV through a semiconductor substrate, including forming a via in the substrate; and forming a multitude of conductive bars in the via. The multitude of conductive bars include at least one signal bar, at least one power bar, and at least one ground bar. The method further comprises connecting the at least one power bar to a power voltage source to apply power through the TSV; connecting the at least one ground bar to a ground voltage; and connecting the at least one signal bar to a source of an electronic signal to conduct the signal through the TSV and to form a hybrid power-ground-signal TSV in the substrate.

Abstract: A semiconductor device includes a semiconductor substrate and a through electrode provided in a through hole formed in the semiconductor substrate. The through electrode partially protrudes from a back surface of the semiconductor substrate, which is opposite to an active surface thereof. The through electrode includes a resin core and a conductive film covering at least a part of the resin core.

Abstract: A semiconductor device includes a gate structure on a semiconductor substrate, an impurity region at a side of the gate structure and the impurity region is within the semiconductor substrate, an interlayer insulating layer covering the gate structure and the impurity region, a contact structure extending through the interlayer insulating layer and connected to the impurity region, and an insulating region. The contact structure includes a first contact structure that has a side surface surrounded by the interlayer insulating layer and a second contact structure that has a side surface surrounded by the impurity region. The insulating region is under the second contact structure.

Abstract: In a multiple gate transistor, the plurality of Fins of the drain or source of the transistor are electrically connected to each other by means of a common contact element, wherein enhanced uniformity of the corresponding contact regions may be accomplished by an enhanced silicidation process sequence. For this purpose, the Fins may be embedded into a dielectric material in which an appropriate contact opening may be formed to expose end faces of the Fins, which may then act as silicidation surface areas.

Abstract: A method of forming an interconnect structure that may reduce or eliminate stress induced voids is provided. In an embodiment, a via is formed below a conductive line to provide an electrical connection to an underlying conductive region. The conductive line includes a widened region above the via. The widened region serves to reduce or eliminate stress induced voids between the via and the underlying conductive region. In another embodiment, one or more redundant lines are formed extending from a conductive region, such as a contact pad, such that the redundant line does not electrically couple the conductive region to an underlying conductive region. In a preferred embodiment, the redundant lines extend from a conductive region on a side adjacent to a side having a conductive line coupled to a via.

Abstract: A barrier insulating film is constituted from a first SiCN film formed with a tetramethylsilane gas flow rate lower than usual, a second SiCN film formed over the first SiCN film and formed with a usual tetramethylsilane gas flow rate, and a SiCO film formed over the second SiCN film.

Abstract: Local interconnect structures and fabrication methods are provided. A dielectric layer can be formed on a semiconductor substrate. A first film layer can be patterned on the dielectric layer to define a region surrounded by a local interconnect structure to be formed. A sidewall spacer can be formed and patterned surrounding the first film layer on an exposed surface portion of the dielectric layer. A second film layer can be formed on the exposed surface portion of the dielectric layer and can have a top surface substantially flushed with a top surface of the sidewall spacer. The patterned sidewall spacer can be removed to form a first opening. After forming the first opening, the dielectric layer can be etched to form a second opening through the dielectric layer. The second opening can be filled with a conductive material to form the local interconnect structure.

Abstract: High aspect ratio trenches may be filled with metal that grows more from the bottom than the top of the trench. As a result, the tendency to form seams or to close off the trench at the top during filling may be reduced in some embodiments. Material that encourages the growth of metal may be formed in the trench at the bottom, while leaving the region of the trench near the top free of such material to encourage growth upwardly from the bottom.

Abstract: Fabrication methods for semiconductor device structures are provided. One method for fabricating a semiconductor device structure involves forming a first layer of a first dielectric material overlying a doped region formed in a semiconductor substrate, forming a first conductive contact electrically connected to the doped region within the first layer, forming a dielectric cap on the first conductive contact, forming a second layer of a second dielectric material overlying the dielectric cap and a gate structure overlying the semiconductor substrate, and forming a second conductive contact electrically connected to the gate structure within the second layer.

Abstract: A semiconductor device includes: a semiconductor substrate; an underlying wiring on the semiconductor substrate; a resin film extending to the semiconductor substrate and the underlying wiring, and having a first opening on the underlying wiring; a first SiN film on the underlying wiring and the resin film, and having a second opening in the first opening; an upper layer wiring on the underlying wiring and part of the resin film; and a second SiN film on the upper layer wiring and the resin film, and joined to the first SiN film on the resin film. The upper layer wiring includes a Ti film, connected to the underlying wiring via the first and second openings, and an Au film on the Ti film. The first and second SiN films circumferentially protect the Ti film.

Abstract: In accordance with the present invention, there is provided a semiconductor device comprising a semiconductor die or chip, a package body and a through package body via. The semiconductor chip includes a plurality of conductive pads. The package body encapsulates a sidewall of the semiconductor chip, and has at least one hole formed therein having a sidewall which is of a prescribed first surface roughness value. The through package body via is disposed in the hole of the package body and comprises a dielectric material and at least one conductive interconnection metal. The dielectric material is disposed on the sidewall of the hole and defines at least one bore having a sidewall which is of a second surface roughness value less than the first surface roughness value. The interconnection metal is disposed within the bore.

Abstract: A wiring board has a first resin insulation layer, a first conductive pattern formed on the first resin insulation layer, a second resin insulation layer formed on the first conductive pattern and having an opening portion exposing at least a portion of the first conductive pattern, a second conductive pattern formed on the second resin insulation layer, and a via conductor formed in the opening portion of the second resin insulation layer and electrically connecting the first conductive pattern and the second conductive pattern. The via conductor has a side surface extending between the first conductive pattern and the second conductive pattern and a bent portion where an inclination of the side surface of the via conductor changes in a depth direction of the via conductor.

Abstract: Structures and methods for the dissipation of charge build-up during the formation of cavities in semiconductor substrates.

Abstract: A method of forming a hybrid interconnect structure including dielectric spacers is provided. The method includes forming at least one opening in a dielectric material utilizing a patterned hard mask located on a surface of the dielectric material as a mask, wherein an undercut is present beneath said patterned hard mask. Next, a dense dielectric spacer is formed in the at least one opening and at least partially on exposed sidewalls of the dielectric material. A diffusion barrier and a conductive material are then formed within the at least one opening.

Abstract: A damascene process incorporating a GCIB step is provided. The GCIB step can replace one or more CMP steps in the traditional damascene process. The GCIB step allows for selectable removal of unwanted material and thus, reduces unwanted erosion of certain nearby structures during damascene process. A GCIB step may also be incorporated in the damascene process as a final polish step to clean up surfaces that have been planarized using a CMP step.

Abstract: The present invention provides a method of forming a via hole (9), or a via (7), from a lower side (5) of a substrate (3) for electronic devices towards an upper side (4) of a substrate (3) at least partly through the substrate (3). The method comprises the steps of: etching a first lengthwise portion (11) of the via hole (9) and etching a second lengthwise portion (12) of the via hole (9); whereby the first lengthwise portion (11) and the second lengthwise portion (12) substantially form the via hole (9) and a constriction (23) is formed in the via hole (9). The constriction (23) defines an aperture (24) of the via hole (9) and the method further comprises the step of opening the via hole (9) by etching, with the constriction (23) functioning as an etch mask. A via is formed by at least partly filling the via hole with conductive material. A substrate for electronic devices comprising a via is also provided.

Abstract: An interconnect element is provided. A monolithic dielectric element has a first exposed major surface, a plurality of first recesses extending inwardly from the first major surface, and a second exposed major surface remote from the first major surface, a plurality of second recesses extending inwardly from the second major surface. A plurality of first metal interconnect patterns are embedded in the plurality of first recesses and extend in one or more directions along the first major surface. A plurality of second metal interconnect patterns are embedded in the plurality of second recesses and extend in one or more directions along the second major surface. A plurality of non-hollow metal posts extend through the dielectric element between at least some of the plurality of first metal interconnect patterns and at least some of the plurality of second metal interconnect patterns.

Abstract: A method for forming a contact window includes: a step of providing a substrate; a step of forming a patterned amorphous carbon layer or spin-on coating layer, in which a surface of the substrate is exposed at two sides of the amorphous carbon layer or spin-on coating layer; a step of forming an interlayer dielectric layer on the substrate; a step of removing a portion of the interlayer dielectric layer until the patterned amorphous carbon layer or spin-on coating layer is exposed; a step of removing the patterned amorphous carbon layer or spin-on coating layer to form an opening; and a step of filling the opening with a conductive material to form the contact window.

Abstract: A semiconductor structure and a manufacturing method thereof are provided. The semiconductor structure includes a stacked structure, a plurality of first conductive blocks, a plurality of first conductive layers, a plurality of second conductive layers, and a plurality of conductive damascene structures. The stacked structure, comprising a plurality of conductive strips and a plurality of insulating strips, is formed on a substrate, and the conductive strips and the insulating strips are interlaced. The first conductive blocks are formed on the stacked structure. The first conductive layers and the second conductive layers are formed on two sidewalls of the stacked structure, respectively. The conductive damascene structures are formed on two sides of the stacked structure, wherein each of the first conductive blocks is electrically connected to each of the conductive damascene structures via each of the first conductive strips and each of the second conductive strips.

Abstract: A semiconductor device of an embodiment includes: a substrate; a first catalytic metal film on the substrate; graphene on the first catalytic metal film; an interlayer insulating film on the graphene; a contact hole penetrating through the interlayer insulating film; a conductive film at the bottom portion of the contact hole, the conductive film being electrically connected to the graphene; a second catalytic metal film on the conductive film, the second catalytic metal film being subjected to plasma processing with at least one kind of gas selected from hydrogen, nitrogen, ammonia, and rare gas; and carbon nanotubes on the second catalytic metal film.

Abstract: A metal layer is deposited on a planar surface on which top surfaces of underlying metal vias are exposed. The metal layer is patterned to form at least one metal block, which has a horizontal cross-sectional area of a metal line to be formed and at least one overlying metal via to be formed. Each upper portion of underlying metal vias is recessed outside of the area of a metal block located directly above. The upper portion of the at least one metal block is lithographically patterned to form an integrated line and via structure including a metal line having a substantially constant width and at least one overlying metal via having the same substantially constant width and borderlessly aligned to the metal line. An overlying-level dielectric material layer is deposited and planarized so that top surface(s) of the at least one overlying metal via is/are exposed.

Abstract: A method for forming a contact opening, such as a via hole, is provided. In the method, a sacrificial layer is deposited over a damascene feature prior to exposing a conductor formed in a substrate at a bottom of the opening. The sacrificial layer is provided to prevent damage or contamination of materials used. Even after the conductor has been exposed once or more times, the sacrificial layer can be deposited over the damascene feature to protect it from further damage or contamination by a subsequent process that will further expose the conductor at the contact opening bottom. The exposing step may form a recess in the conductor. By further forming a trench feature over the contact opening, a dual damascene feature can be fabricated.

Abstract: The PCRAM device includes a semiconductor substrate including a switching device; an interlayer insulating layer having a heating electrode contact hole exposing the switching device, a heating electrode formed to be extended along a side of the interlayer insulating layer in the heating electrode contact hole, wherein the heating electrode has a width gradually increased toward a bottom of the heating electrode and is in contact with the switching device, first and second phase-change layers formed within the heating electrode contact hole that includes the heating electrode, and a phase-change separation layer formed in the heating electrode contact hole between the first and second phase-change layers.

Abstract: A self-aligned source/drain contact formation process without spacer or cap loss is described. Embodiments include providing two gate stacks, each having spacers on opposite sides, and an interlayer dielectric (ILD) over the two gate stacks and in a space therebetween, forming a vertical contact opening within the ILD between the two gate stacks, and laterally removing ILD between the two gate stacks from the vertical contact opening toward the spacers, to form a contact hole.

Abstract: Narrow word lines are formed in a NAND flash memory array using a double patterning process in which sidewall spacers define word lines. Sidewall spacers also define edges of select gates so that spacing between a select gate and the closest word line is equal to spacing between adjacent word lines.

Abstract: A semiconductor device includes: a semiconductor substrate including a first face and a second face on a side opposite to the first face; an external connection terminal formed on the first face of the semiconductor substrate; a first electrode formed on the first face of the semiconductor substrate and electrically connected to the external connection terminal; an electronic element formed on or above the second face of the semiconductor substrate; a second electrode electrically connected to the electronic element and having a top face and a rear face; a groove portion formed on the second face of the semiconductor substrate and having a bottom face including at least part of the rear face of the second electrode; and a conductive portion formed in the groove portion and electrically connected to the rear face of the second electrode.

Abstract: A method of high aspect ratio contact etching a substantially vertical contact hole in an oxide layer using a hard photoresist mask is described. The oxide layer is deposited on an underlying substrate. A plasma etching gas is formed from a carbon source gas. Dopants are mixed into the gas. The doped plasma etching gas etches a substantially vertical contact hole through the oxide layer by doping carbon chain polymers formed along the sidewalls of the contact holes during the etching process into a conductive state. The conductive state of the carbon chain polymers reduces the charge buildup along sidewalls to prevent twisting of the contact holes by bleeding off the charge and ensuring proper alignment with active area landing regions. The etching stops at the underlying substrate.

Abstract: A semiconductor chip includes a seal ring adjacent to edges of the semiconductor chip; an opening extending from a top surface to a bottom surface of the seal ring, wherein the opening has a first end on an outer side of the seal ring and a second end on an inner side of the seal ring; and a moisture barrier having a sidewall parallel to a nearest side of the seal ring, wherein the moisture barrier is adjacent the seal ring and has a portion facing the opening.