Abstract: An aluminum lateral interconnect of a Back End of the Line (BEOL) is used to define the x and y dimensions of a through-silicon via in a semiconductor chip formed in a silicon substrate. The TSV includes one or more aluminum annulus formed on a surface of the substrate, and a deep trench in the substrate having a diameter that is determined by the diameter of the aluminum annulus. The annulus can also be provided with a conductive strap upon which a capacitor can be formed. The strap can also be used to provide a connection of the TV to other BEOL interconnects.

Abstract: A high voltage integrated circuit device includes a semiconductor substrate having a surface region with a contact region, which is coupled to a source/drain region. The device has a plasma enhanced oxide overlying the surface region, a stop layer overlying the plasma enhanced oxide, and a contact opening through a portion of the stop layer and through a portion of the plasma enhanced oxide layer. The contact opening exposes a portion of the contact region without damaging it. The device has a silicide layer overlying the contact region to form a silicided contact region and an interlayer dielectric overlying the silicided contact region to fill the contact opening and provide a thickness of material overlying the stop layer. An opening in the interlayer dielectric layer is formed through a portion of the thickness to expose a portion of the silicided contact region and expose a portion of the stop layer.

Abstract: A semiconductor device manufacturing method includes: stacking a plurality of electrode layers containing a semiconductor alternately with insulating layers; processing part of a multilayer body of the electrode layers and the insulating layers into a staircase shape and exposing a surface of the staircase-shaped electrode layers; forming a metal film in contact with the exposed electrode layers; reacting the semiconductor of the electrode layers with the metal film to form a metal compound in at least a portion of the electrode layers in contact with the metal film; removing an unreacted portion of the metal film; forming an interlayer insulating layer covering the staircase-shaped electrode layers after removing the unreacted portion of the metal film; forming a plurality of contact holes piercing the interlayer insulating layer, each of the contact holes reaching the metal compound of the electrode layer at a corresponding stage; and providing a plurality of contact electrodes inside the contact holes.

Abstract: The present invention relates to a metal wiring of a semiconductor device and a method for the same, and is directed to disclose a technique forming an additional conductive layer within the metal line, which acts as an etching barrier to increase the etching margin and to improve the RC characteristics between the metal lines, which can prevent the Cu migration.

Abstract: A three-dimensional (3D) chip stack structure and method of fabricating the structure thereof are provided. The 3D chip stack structure includes a plurality of vertically stacked chips which are interconnected and bonded together, wherein each of the vertically stacked chips include one or more IC device strata. The 3D chip stack structure further includes an air channel interconnect network embedded within the chip stack structure, and wherein the air channel interconnect network is formed in between at least two wafers bonded to each other of the vertically stacked wafers and in between at least two bonded wafers of the vertically stacked wafers at a bonding interface thereof.

Abstract: Embodiments relate to a method of manufacturing a semiconductor device that may simplify a manufacturing process and may reduce process costs. According to embodiments, the method may include simultaneously forming a first gate of a first device area and a second gate of a second device area, patterning a PMD layer to form a first contact hole exposing the first gate, depositing and planarizing a high dielectric constant material and first and second metallic materials on the semiconductor substrate to expose PMD layer, forming an insulating layer, a metal layer and a third gate in the first contact hole, patterning the PMD layer to form a second contact hole exposing the second gate, and depositing a third metallic material on the semiconductor substrate and planarizing it such that the PMD layer is exposed, thereby forming a contact in the second contact hole.

Abstract: A structure and method of forming low cost bond pads is described. In one embodiment, the invention includes depositing an insulating layer over a last metal line of a substrate and forming an opening in the insulating layer. A colloid is printed over the insulating layer and fills the opening in the insulating layer. A conductive via and bond pads are formed by heating the colloid.

Abstract: A silicon-based low-k dielectric material is formed on the basis of a single precursor material, such as OMTCS, without incorporating a porogen species. To this end, the initial deposition of the low-k dielectric material may be formed on the basis of a reduced process temperature, while a subsequent treatment, such as a UV treatment, may allow the adjustment of the final material characteristics without causing undue out-gassing of volatile organic components.

Abstract: To provide a technique capable of improving the reliability on electric properties of a semiconductor device by devising the shape of the upper surface of a plug. A plug of the present invention has an upwardly convex dome-like shape in which the upper surface thereof projects from the surface (upper surface) of a contact interlayer insulating film. That is, the plug has the upper surface of an upwardly convex dome-like shape, wherein the height of the top edge portion of a barrier conductive film is larger than that of the upper surface of the contact interlayer insulating film, and the height of the top edge portion of a tungsten film is larger than that of the top edge portion of the barrier conductive film.

Abstract: The present disclosure relates to methods and solutions for growing metal charge-transfer salts on a metal surface, such as a metal layer at the bottom of a via hole. The method makes use of a solution comprising a salt additive. The temperature during growth is in the range of ?100° C. to +100° C. The method allows controlled growth of the metal charge transfer salt inside via hole while limiting growth outside the via hole. The method further limits corrosion of the metallic connections at the bottom of the via hole.

Abstract: A method for manufacturing an electronic component on a semiconductor substrate, including forming at least one opening in the substrate; forming in the bottom and on the walls of the opening and on the substrate an alternated succession of layers of a first material and of a second material, the second material being selectively etchable with respect to the first material and the substrate; trimming the layer portions of the first material and of the second material which are not located in the opening; selectively etching a portion of the first material to obtain trenches; and filling the trenches with at least one third material.

Abstract: There is provide a semiconductor device manufacturing method, including: preparing a substrate; laminating an insulation layer on the substrate; laminating a first underlying metal layer on the insulation layer; forming rewiring on the first underlying metal layer; removing exposed portions of the first underlying metal layer; laminating a second underlying metal layer on the rewiring and the insulation layer; forming a column electrode on the rewiring via the second underlying metal layer; and removing exposed portions of the second underlying metal layer.

Abstract: A via connecting the front surface of a substrate to its rear surface, this substrate including a porous region extending from at least a portion of the periphery of the via, the via including outgrowths extending in pores of the porous region.

Abstract: According to an exemplary embodiment, a semiconductor die including at least one deep silicon via is provided. The deep silicon via comprises a deep silicon via opening that extends through at least one pre-metal dielectric layer of the semiconductor die, at least one epitaxial layer of the semiconductor die, and partially into a conductive substrate of the semiconductor die. The deep silicon via further comprises a conductive plug situated in the deep silicon via opening and forming an electrical contact with the conductive substrate. The deep silicon via may include a sidewall dielectric layer and a bottom conductive layer. A method for making a deep silicon via is also disclosed. The deep silicon via is used to, for example, provide a ground connection for power transistors in the semiconductor die.

Abstract: A via connecting the front surface of a substrate to its rear surface and having, in cross-section in a plane parallel to the surfaces, the shape of a scalloped ring.

Abstract: A via connecting the front surface of a semiconductor substrate to its rear surface, this via having a rough lateral surface.

Abstract: A method of manufacturing a semiconductor package, including at least a step A that forms a first transforming portion by irradiating a laser beam on at least a portion of a first substrate; a step B that joins together the first substrate and a second substrate in which a functional element is disposed; a step C that removes the first transforming portion that is disposed on the first substrate by etching; and a step D that forms a conductive portion in the first substrate by filling a conductive material in a portion where the first transforming portion has been removed.

Abstract: An integrated device, including: a first conductive region; a second conductive region set at a distance from the first conductive region; an etch-stop layer, made of a first dielectric material, at least partially overlapped on the first and second conductive regions; an insulating layer, made of a second dielectric material, different from the first, overlapped on the first and second conductive regions and on the etch-stop layer; at least one through opening extending through the insulating layer and the etch-stop layer; and a barrier layer, made of a third dielectric material, different from the first, set between the first conductive region and the etch-stop layer and between the second conductive region and the etch-stop layer.

Abstract: A method of fabricating a semiconductor device is provided which includes providing a substrate. A material layer is formed over the substrate. A polymer layer is formed over the material layer. A nano-sized feature is self-assembled using a portion of the polymer layer. The substrate is patterned using the nano-sized feature.

Abstract: A method of forming an interconnect structure, comprising forming a first interconnect layer (123) embedded in a first dielectric layer (118), forming a dielectric tantalum nitride barrier (150) by means of atomic layer deposition on the surface of the first interconnect (123), depositing a second dielectric layer (134) over the first interconnect (123) and the barrier (150) and etching a via (154) in the dielectric layer (134) to the barrier (150). The barrier (150) is then exposed to a treatment through the via (154) to change it from the dielectric phase to the conductive phase (180) and the via (154) is subsequently filled with conductive material (123).

Abstract: Methods are provided for fabricating silicon carriers with conductive through-vias that allow high-yield manufacture of silicon carrier with low defect density. In particular, methods are provided which enable fabrication of silicon carries with via diameters such as 1 to 10 microns in diameter for a vertical thickness of less than 10 micrometers to greater than 300 micrometers, which are capable robust to thermal-mechanical stresses during production to significantly minimize the thermal mechanical movement at the via sidewall interface between the silicon, insulator, liner and conductor materials.

Abstract: In sophisticated semiconductor devices, non-insulating materials with extremely high internal stress level may be used in the contact level in order to enhance performance of circuit elements, such as field effect transistors, wherein the non-insulating material may be appropriately “encapsulated” by dielectric material. Consequently, a desired high strain level may be obtained on the basis of a reduced layer thickness, while still providing the insulating characteristics required in the contact level.

Abstract: A circuit substrate uses post-fed top side power supply connections to provide improved routing flexibility and lower power supply voltage drop/power loss. Plated-through holes are used near the outside edges of the substrate to provide power supply connections to the top metal layers of the substrate adjacent to the die, which act as power supply planes. Pins are inserted through the plated-through holes to further lower the resistance of the power supply path(s). The bottom ends of the pins may extend past the bottom of the substrate to provide solderable interconnects for the power supply connections, or the bottom ends of the pins may be soldered to “jog” circuit patterns on a bottom metal layer of the substrate which connect the pins to one or more power supply terminals of an integrated circuit package including the substrate.

Abstract: Improved control over formation of low k air gaps in interlayer insulating films is achieved by plasma pretreatment of the region of the insulating film to be removed. The intended air gap region is exposed through a mask while the film region to be preserved is shielded by the mask. The intended air gap region is then exposed to a plasma so as to render it more susceptible to removal in a subsequent treatment. One or more Cu interconnects are embedded in both regions of the insulator film. The insulator film in the intended air gap region is then selectively removed to form air gaps adjacent a Cu interconnect in that region.

Abstract: A method of fabricating a landing plug in a semiconductor memory device, which in one embodiment includes forming a landing plug contact hole on a semiconductor substrate having an impurity region to expose the impurity region; forming a landing plug by filling the landing plug contact hole with a polysilicon layer, wherein the landing plug is divided into a first region, a second region, a third region, and a fourth region from a lower portion of the landing plug, and the first region is doped with a first doping concentration that is relatively lowest, the second region is doped with a second doping concentration that is higher than the first doping concentration, the third region is doped with a third doping concentration that is higher than the second doping concentration and the fourth region is not doped; and annealing the resulting product formed with the landing plug.

Abstract: One embodiment of the invention provides a method of forming a plurality of contact holes, including forming a first feature and a second feature over an underlying material, forming sidewall spacers on the first and second features, removing the first and second features without removing the sidewall spacers, forming a cover mask at least partially exposing the sidewall spacers, and etching the underlying material using the cover mask and the sidewall spacers as a mask to form the plurality of contact holes.

Abstract: A method for fabricating a semiconductor device with a buried gate includes: etching a substrate to form a plurality of trenches; forming a plurality of buried gates that fill lower portions of the trenches; forming a plurality of sealing layers that gap-fill upper portions of the trenches and have protrusions higher than a top surface of the substrate; forming an inter-layer insulation layer over the whole surface of the substrate including the sealing layers; and etching the inter-layer insulation layer to form a contact hole that is aligned with a space between the protrusions of the sealing layers.

Abstract: Structures including a refractory metal collar at a copper wire and dielectric layer liner-less interface, and a related method, are disclosed. In one embodiment, a structure includes a copper wire having a liner-less interface with a dielectric layer thereabove; a via extending upwardly from the copper wire through the dielectric layer; and a refractory metal collar extending from a side of the via and partially along the liner-less interface. Refractory metal collar prevents electromigration induced slit voiding by improving the interface around the via, and prevents void nucleation from occurring near the via. Also, the refractory metal collar provides electrical redundancy in the presence of voids around the via and dielectric layer liner-less interface.

Abstract: An IC chip and design structure having a TWV contact contacting the TWV and extending through a second dielectric layer over the TWV. An IC chip may include a substrate; a through wafer via (TWV) extending through at least one first dielectric layer and into the substrate; a TWV contact contacting the TWV and extending through a second dielectric layer over the TWV; and a first metal wiring layer over the second dielectric layer, the first metal wiring layer contacting the TWV contact.

Abstract: Provided are a semiconductor device and a method of fabricating the semiconductor memory device. A contact plug is formed by wet etching. An aspect ratio of SAC is decreased and SAC fail is reduced so that a process margin is secured. The semiconductor device includes a semiconductor substrate comprising an active region and a device isolation layer defining the active region, a conductive pattern formed on the semiconductor substrate, and a nitride layer formed on the semiconductor substrate perpendicularly to the conductive pattern.

Abstract: A semiconductor device is made by mounting a prefabricated heat spreader frame over a temporary substrate. The heat spreader frame includes vertical bodies over a flat plate. A semiconductor die is mounted to the heat spreader frame for thermal dissipation. An encapsulant is deposited around the vertical bodies and semiconductor die while leaving contact pads on the semiconductor die exposed. The encapsulant can be deposited using a wafer level direct/top gate molding process or wafer level film assist molding process. An interconnect structure is formed over the semiconductor die. The interconnect structure includes a first conductive layer formed over the semiconductor die, an insulating layer formed over the first conductive layer, and a second conductive layer formed over the first conductive layer and insulating layer. The temporary substrate is removed, dicing tape is applied to the heat spreader frame, and the semiconductor die is singulated.

Abstract: A method of manufacturing a semiconductor device comprises forming an insulating layer on a semiconductor substrate, etching the insulating layer to form contact regions, forming a conductive layer on an entire surface including the contact regions, and spiking the conductive layer in the semiconductor substrate.

Abstract: A method for manufacturing a semiconductor device is disclosed in which, after semiconductor function regions and patterns of interlayer insulating films including required contact holes are formed on one main surface side of a semiconductor substrate, an aluminum film or an aluminum alloy film which is thick is formed all over the main surface side of the semiconductor substrate and brought into conductive contact with the surface of the semiconductor substrate including bottom surfaces of the contact holes so as to form a required electrode film. Formation of the aluminum film or the aluminum alloy film is divided into a plurality of steps so that the thickness of the aluminum film or the aluminum alloy film is formed gradually, and between every two of the plurality of steps of forming the aluminum film or the aluminum alloy film, there is provided a step of performing isotropic etching to flatten irregularities in a surface of the aluminum film or the aluminum alloy film formed in the previous step.

Abstract: A method for fabricating through-silicon via structure is disclosed. The method includes the steps of: providing a semiconductor substrate; forming at least one semiconductor device on surface of the semiconductor substrate; forming a dielectric layer on the semiconductor device, in which the dielectric layer includes at least one via hole; forming a first conductive layer on the dielectric layer and filling the via hole; performing an etching process to form a through-silicon via in the first conductive layer, the dielectric layer, and the semiconductor substrate; depositing a second conductive layer in the through-silicon via and partially on the first conductive layer; and planarizing a portion of the second conductive layer until reaching the surface of the first conductive layer.

Abstract: A method of producing a semiconductor device having a plurality of wiring layers forms a first interlayer-insulating film, forms a plurality of grooves for wiring in the first interlayer-insulating film, fills metallic films in the grooves to form wirings, etches the first interlayer-insulating film with the wirings as a mask and removes the interlayer-insulating film between the wirings to provide grooves to be filled, and fills a second interlayer-insulating film made of a material of low dielectric constant in the grooves to be filled.

Abstract: A nitride crystal is characterized in that, in connection with plane spacing of arbitrary specific parallel crystal lattice planes of the nitride crystal obtained from X-ray diffraction measurement performed with variation of X-ray penetration depth from a surface of the crystal while X-ray diffraction conditions of the specific parallel crystal lattice planes are satisfied, a uniform distortion at a surface layer of the crystal represented by a value of |d1-d2|/d2 obtained from the plane spacing d1 at the X-ray penetration depth of 0.3 ?m and the plane spacing d2 at the X-ray penetration depth of 5 ?m is equal to or lower than 2.1×10?3.

Abstract: A semiconductor wafer has a plurality of semiconductor die separated by a peripheral region. A trench is formed in the peripheral region of the wafer. A via is formed the die. The trench extends to and is continuous with the via. A first conductive layer is deposited in the trench and via to form conductive TSV. The first conductive layer is conformally applied or completely fills the trench and via. The trench has a larger area than the vias which accelerates formation of the first conductive layer. A second conductive layer is deposited over a front surface of the die. The second conductive layer is electrically connected to the first conductive layer. The first and second conductive layers can be formed simultaneously. A portion of a back surface of the wafer is removed to expose the first conductive layer. The die can be stacked and electrically interconnected through the TSVs.

Abstract: Test structures for semiconductor devices, methods of forming test structures, semiconductor devices, methods of manufacturing thereof, and testing methods for semiconductor devices are disclosed. In one embodiment, a test structure for a semiconductor device includes at least one first contact pad disposed in a first material layer in a scribe line region of the semiconductor device. The at least one first contact pad has a first width. The test structure also includes at least one second contact pad disposed in a second material layer proximate the at least one first contact pad in the first material layer. The at least one second contact pad has a second width that is greater than the first width.

Abstract: An integrated circuit comprising one or more dielectric layers the or each dielectric layer being provided with one or more interconnects wherein the interconnect comprises metallic atoms moving from a first region of the interconnect to a second region of the interconnect when a current flows, characterised in that the interconnect comprises a donor zone in the first region of the interconnect for providing metallic atoms in order to compensate for movement of atoms from the first region and a receptor zone at the second region of the interconnect for receiving metallic atoms in order to compensate for movement of atoms to the second region.

Abstract: A method of manufacture of an integrated circuit system includes: fabricating a substrate having an integrated circuit; applying a low-K dielectric layer over the integrated circuit; forming a via and a trench, in the low-K dielectric layer, over the integrated circuit; forming a structure surface by a chemical-mechanical planarization (CMP) process; and applying a direct implant to the structure surface for forming an implant layer and a metal passivation layer including repairing damage, to the low-K dielectric layer, caused by the CMP process.

Abstract: A semiconductor device includes: a semiconductor substrate; an interlayer insulating film provided on the semiconductor substrate; an interconnect (second interconnect trench) composed of a metallic film provided in an interconnect trench (second copper interconnect) and a plug composed of a metallic film provided in a connection hole (via hole) coupled to the second interconnect trench, both of which are provided in the interlayer insulating film; a first sidewall provided on a side surface of the via hole; and a second sidewall provided on a side surface of the second interconnect trench, and a thickness of the first sidewall in vicinity of a bottom of the side surface of the via hole is larger than a thickness of the second sidewall in vicinity of a bottom of the second interconnect trench.

Abstract: A method for making an integrated circuit device by: forming a plurality of transistors on a semiconductor substrate; forming multilayer interconnects by depositing a layer of metal; patterning the metal layer; depositing a first dielectric material, depositing a second dielectric material, patterning the first and second dielectric materials; and depositing a via filling metal material into the patterned areas; or, alternatively, by forming transistors on a substrate; depositing one of an electrically insulating or electrically conducting material; patterning said one of an electrically insulating or electrically conducting material; and depositing the other of the electrically insulating or electrically conducting material, so as to form a layer over said transistors having both electrically insulating and electrically conducting portions; wherein the first dielectric material, which is an organosiloxane material, and the electrically insulating material each has a carbon to silicon ratio of 1.

Abstract: Methods of forming metal silicide layers. The methods include: forming a silicon-rich layer between dielectric layers; contacting the silicon-rich layer with a metal layer and heating the silicon rich-layer and the metal layer to diffuse metal atoms from the metal layer into the silicon layer to form a metal silicide layer.

Abstract: The formation of electronic assemblies including a die having through vias is described. In one embodiment, a method includes providing Si die including a first surface and a second surface opposite the first surface, and forming a via extending through the Si die from the first surface to the second surface. The via is formed to have a larger width at the first surface than at the second surface, the larger width at the first surface being no less than 100 microns. The method also includes placing a plurality of particles in the via, wherein at least some of the particles comprise a polymer and at least some of the particles comprise a metal. The method also includes heating the die and the particles in the via to cross-link at least part of the polymer in the via, and cooling the die to solidify the polymer and form a electrically conductive composite including the cross-linked polymer and the metal in the via. Other embodiments are described and claimed.

Abstract: A three-state mask, which is used during exposure of a lithography process and formed in a regular pattern, includes a first transmission region to transmit substantially all incident light, second transmission regions to transmit a portion of incident light, and shield regions to block transmission of light. Therefore, the three-state mask shortens two lithography processes into one lithography process, eliminates misalignment between a via hole and a trench, prevents lowering of a sheet resistance (Rs) due to misalignment, simplifies a dual damascene process, reduces the number of masks used in the dual damascene process, and thus contributes to reduction of manufacturing costs of the semiconductor device.

Abstract: A method of forming a semiconductor device includes forming a first interlevel dielectric (ILD) layer over one or more transistor structures formed on a substrate, the one or more transistor structures including an active area, source/drain contact and a gate conductor formed over the substrate; forming a first metal (M1) level trench in an upper portion of the first ILD layer, followed by forming vias in a lower portion of the first ILD layer, down to the source/drain contact and down to the gate conductor; and filling both the trench and vias with a conductive material, thereby resulting in a dual damascene metal process at and below the M1 level of the semiconductor device.

Abstract: The present disclosure provides a semiconductor device that includes, a substrate; a first conductive line located over the substrate and extending along a first axis, the first conductive line having a first length and a first width, the first length being measured along the first axis; a second conductive line located over the first conductive line and extending along a second axis different from the first axis, the second conductive line having a second length and a second width, the second length being measured along the second axis; and a via coupling the first and second conductive lines, the via having an upper surface that contacts the second conductive line and a lower surface that contacts the first conductive line. The via has an approximately straight edge at the upper surface, the straight edge extending along the second axis and being substantially aligned with the second conductive line.

Abstract: An integrated circuit may include a region containing a thermoelectric material and be configured to be subjected to a temperature gradient resulting from a flow of an electric current in a part of the integrated circuit during its operation, and an electrically conducting output coupled to the region for delivering the electrical energy produced by thermoelectric material.

Abstract: A semiconductor integrated circuit device includes a semiconductor substrate; a dummy pattern extending in one direction on the semiconductor substrate; a junction region electrically connecting the dummy pattern to the semiconductor substrate; and a voltage applying unit that is configured to apply a bias voltage to the dummy pattern.

Abstract: A semiconductor device package and fabricating method thereof are disclosed, by which heat-dissipation efficiency is enhanced in a system by interconnection (SBI) structure. An exemplary semiconductor device package may include a substrate, at least two chips mounted on the substrate to have a space between one or more of the chips and an edge of the substrate, an insulating layer covering the chips, the insulating layer having via holes exposing portions of the at least two chips and a trench between the via holes, the insulating layer having at least two hole patterns within the space, and a metal layer filling the via holes and the trench.