Abstract: The present invention provides approaches for electroless deposition of conductive materials onto the surface of oxide-based materials, including nonconductive metal oxides, in a manner that does not require intervening conductive pastes, nucleation layers, or additional seed or activation layers formed over the surface of the oxide-based layer. According to one embodiment of the present invention, a layer of a titanium-based material is formed over an oxide-based surface. The layer of titanium-based material is subsequently removed from the surface of the oxide-based layer in a manner such that the surface of the oxide-based layer is activated for electroless deposition. A metal or metal alloy is then plated over the oxide-based surface using electroless plating techniques.

Abstract: A method for substantially simultaneously polishing a copper conductive structure of a semiconductor device structure and an adjacent barrier layer includes use of a fixed-abrasive type polishing pad with a substantially abrasive-free slurry in which copper is removed at a rate that is substantially the same as or faster than a rate at which a material, such as tungsten, of the barrier layer is removed. The slurry is formulated so as to oxidize copper at substantially the same rate as or at a faster rate than a material of the barrier layer is oxidized. Thus, copper and the barrier layer material have substantially the same oxidation energies in the slurry or the oxidation energy of the barrier layer material in the slurry may be greater than that of copper. Systems for substantially polishing copper conductive structures and adjacent barrier structures on semiconductor device structures are also disclosed.

Abstract: A scheme for filling plugs through chemical mechanical polishing comprises depositing a malleable conductive layer over a dielectric layer having openings formed therein. The malleable conductive layer is deposited such that a liner is formed within the openings, however the openings are not completely filled. A chemical mechanical polishing process using an alumina based slurry at a neutral or slightly basic pH and no oxidizer is used to smear the malleable conductive layer sufficiently to fill the remainder of the openings in the dielectric layer forming filled or substantially filled plugs.

Abstract: A semiconductor component includes a die having a pattern of die contacts, and interconnect contacts bonded to the die contacts and encapsulated in an insulating layer. The component also includes terminal contacts formed on tip portions of the interconnect contacts. Alternately the component can include conductors and bonding pads in electrical communication with the interconnect contacts configured to redistribute the pattern of the die contacts. A method for fabricating the component includes the steps of forming the interconnect contacts on the die contacts, and forming the insulating layer on the interconnect contacts while leaving the tip portions exposed. The method also includes the step of forming the terminal contacts on the interconnect contacts, or alternately forming the conductors and bonding pads in electrical communication with the interconnect contacts and then forming the terminal contacts on the bonding pads.

Abstract: Microelectronic devices with improved heat dissipation, methods of making microelectronic devices, and methods of cooling microelectronic devices are disclosed herein. In one embodiment, the microelectronic device includes a microelectronic substrate having a first surface, a second surface facing opposite from the first surface, and a plurality of active devices at least proximate to the first surface. The second surface has a plurality of heat transfer surface features that increase the surface area of the second surface. In another embodiment, an enclosure having a heat sink and a single or multi-phase thermal conductor can be positioned adjacent to the second surface to transfer heat from the active devices.

Abstract: Methods for fabricating a conductive contact (through-via) through a full thickness of a substrate such as a semiconductor wafer or interposer substrate, and semiconductor devices and systems incorporating the conductive through-via are provided. The conductive contact is fabricated by applying a metal layer onto a backside of a substrate, forming a through-hole through the substrate and the metal layer, sealing the hole in the metal layer by an electroless plating process, and filling the hole by an electroplating or an electroless plating process.

Abstract: A method is described for filling of high aspect ratio contact vias provided over silicon containing areas. A via is formed in an insulating layer over the silicon containing area and a silicide forming material is deposited in the via. A silicide region is formed over the silicon containing area, the silicide forming material is removed from the via leaving the silicide region. The via is then filled with a conductor using an electroless plating process.

Abstract: The invention includes a method of forming spaced conductive regions. A construction is formed which includes a first electrically conductive material over a semiconductor substrate. The construction also includes openings extending through the first electrically conductive material and into the semiconductor substrate. A second electrically conductive material is formed within the openings and over the first electrically conductive material and is in electrical contact with the first electrically conductive material. The second electrically conductive material is subjected to anodic dissolution while the first electrically conductive material is electrically connected to a power source.

Abstract: A method of forming a conductive interconnect, preferably a copper interconnect, comprising a metal cap formed thereover. The metal cap is preferably comprises silver, gold, cobalt, nickel-tungsten, cobalt-tungsten, silver-tungsten or nickel. The conductive interconnect is fabricated by forming a substrate having a trench formed therein, forming a barrier layer over the substrate and within the trench, forming a conductive layer over the barrier layer and within the trench, planarizing the conductive layer to an upper surface of the barrier layer, recessing the conductive layer below an upper surface of the barrier layer, and forming a metal layer over the conductive layer via electroplating.

Abstract: A scheme for filling plugs through chemical mechanical polishing comprises depositing a malleable conductive layer over a dielectric layer having openings formed therein. The malleable conductive layer is deposited such that a liner is formed within the openings, however the openings are not completely filled. A chemical mechanical polishing process using an alumina based slurry at a neutral or slightly basic pH and no oxidizer is used to smear the malleable conductive layer sufficiently to fill the remainder of the openings in the dielectric layer forming filled or substantially filled plugs.

Abstract: A scheme for filling plugs through chemical mechanical polishing comprises depositing a malleable conductive layer over a dielectric layer having openings formed therein. The malleable conductive layer is deposited such that a liner is formed within the openings, however the openings are not completely filled. A chemical mechanical polishing process using an alumina based slurry at a neutral or slightly basic pH and no oxidizer is used to smear the malleable conductive layer sufficiently to fill the remainder of the openings in the dielectric layer forming filled or substantially filled plugs.

Abstract: The invention includes a method of electroless deposition of nickel over an aluminum-containing material. A mass is formed over the aluminum-containing material, with the mass predominantly comprising a metal other than aluminum. The mass is exposed to palladium, and subsequently nickel is electroless deposited over the mass. The invention also includes a method of electroless deposition of nickel over aluminum-containing materials and copper-containing materials. The aluminum-containing materials and copper-containing materials are both exposed to palladium-containing solutions prior to electroless deposition of nickel over the aluminum-containing materials and copper-containing materials. Additionally, the invention includes a method of forming a solder bump over an aluminum-containing material.

Abstract: The invention includes methods of forming capacitor structures and removing organic material. An organic material, such as a photoresist, is disposed on a substrate. The organic material is contacted with a chemical mechanical polishing pad and a polishing fluid to remove the organic material from the substrate. The polishing fluid can be essentially free of particles, and can be water.

Abstract: A method is described for filling of high aspect ratio contact vias provided over silicon containing areas. A via is formed in an insulating layer over the silicon containing area and a silicide forming material is deposited in the via. A silicide region is formed over the silicon containing area, the silicide forming material is removed from the via leaving the silicide region. The via is then filled with a conductor using an electroless plating process.

Abstract: The present invention is generally directed to various methods of forming conductive through-wafer vias. In one illustrative embodiment, the method comprises providing a layer of semiconducting material, forming a layer of metal on a first side of the layer of semiconducting material, forming an opening in the layer of semiconducting material to thereby expose a portion of the layer of metal, the opening extending from at least a second side of the layer of semiconducting material to the layer of metal, and performing a deposition process to form a conductive contact in the opening using the exposed portion of the metal layer as a seed layer.

Abstract: Microelectronic devices with improved heat dissipation, methods of making microelectronic devices, and methods of cooling microelectronic devices are disclosed herein. In one embodiment, the microelectronic device includes a microelectronic substrate having a first surface, a second surface facing opposite from the first surface, and a plurality of active devices at least proximate to the first surface. The second surface has a plurality of heat transfer surface features that increase the surface area of the second surface. In another embodiment, an enclosure having a heat sink and a single or multi-phase thermal conductor can be positioned adjacent to the second surface to transfer heat from the active devices.

Abstract: The invention includes methods of forming capacitor structures and removing organic material. An organic material, such as a photoresist, is disposed on a substrate. The organic material is contacted with a chemical mechanical polishing pad and a polishing fluid to remove the organic material from the substrate. The polishing fluid can be essentially free of particles, and can be water.

Abstract: The invention includes a method of forming spaced conductive regions. A construction is formed which includes a first electrically conductive material over a semiconductor substrate. The construction also includes openings extending through the first electrically conductive material and into the semiconductor substrate. A second electrically conductive material is formed within the openings and over the first electrically conductive material and is in electrical contact with the first electrically conductive material. The second electrically conductive material is subjected to anodic dissolution while the first electrically conductive material is electrically connected to a power source.

Abstract: Microelectronic devices with improved heat dissipation, methods of making microelectronic devices, and methods of cooling microelectronic devices are disclosed herein. In one embodiment, the microelectronic device includes a microelectronic substrate having a first surface, a second surface facing opposite from the first surface, and a plurality of active devices at least proximate to the first surface. The second surface has a plurality of heat transfer surface features that increase the surface area of the second surface. In another embodiment, an enclosure having a heat sink and a single or multi-phase thermal conductor can be positioned adjacent to the second surface to transfer heat from the active devices.

Abstract: The present invention provides approaches for electroless deposition of conductive materials onto the surface of oxide-based materials, including nonconductive metal oxides, in a manner that does not require intervening conductive pastes, nucleation layers, or additional seed or activation layers formed over the surface of the oxide-based layer. According to one embodiment of the present invention, a layer of a titanium-based material is formed over an oxide-based surface. The layer of titanium-based material is subsequently removed from the surface of the oxide-based layer in a manner such that the surface of the oxide-based layer is activated for electroless deposition. A metal or metal alloy is then plated over the oxide-based surface using electroless plating techniques.