Abstract: Light emitting diode (LED) package structures employing large area substrates are described. Panel or reel-to-reel substrate processing is utilized in the manufacture of such LED package structures. In some embodiments, electrochemically deposited metal patterns and through substrate vias (TSuVs) are formed through glass substrates and/or interposers. In some embodiments, the metal deposited into the TSuVs offer high thermal conductivity a low coefficient of thermal expansion (CTE) that is to closely match the CTE of the glass. Singulated LED package structures including a plurality of LEDs arrayed for displays, such as, but not limited to, liquid crystal displays (LCDs) and LED displays or for general purpose LED light sources are described, as are LED package structures including active devices (e.g., ICs) and/or passive devices (e.g., capacitors, inductors, resistors, etc.) integrated with LEDs at the package level.

Abstract: Through substrate via (TSuV) structures and method of making the same are disclosed herein. In embodiments, TSuV structures are metal filled selectively to avoid forming significant metal overburden on non-via surfaces of the substrate. In certain embodiments, post-fill metal removal/planarization operations are eliminated for reduced process complexity and manufacturing cost. In embodiments, selective metal fill entails selective electroless or electrolytic deposition. Both front side and back side selective deposition methods are described along with features of through substrate via structures made with such methods.

Abstract: Light emitting diode (LED) package structures employing large area substrates are described. Panel or reel-to-reel substrate processing is utilized in the manufacture of such LED package structures. In some embodiments, electrochemically deposited metal patterns and through substrate vias (TSuVs) are formed through glass substrates and/or interposers. In some embodiments, the metal deposited into the TSuVs offer high thermal conductivity a low coefficient of thermal expansion (CTE) that is to closely match the CTE of the glass. Singulated LED package structures including a plurality of LEDs arrayed for displays, such as, but not limited to, liquid crystal displays (LCDs) and LED displays or for general purpose LED light sources are described, as are LED package structures including active devices (e.g., ICs) and/or passive devices (e.g., capacitors, inductors, resistors, etc.) integrated with LEDs at the package level.

Abstract: Light emitting diode (LED) package structures employing large area substrates are described. Panel or reel-to-reel substrate processing is utilized in the manufacture of such LED package structures. In some embodiments, electrochemically deposited metal patterns and through substrate vias (TSuVs) are formed through glass substrates and/or interposers. In some embodiments, the metal deposited into the TSuVs offer high thermal conductivity a low coefficient of thermal expansion (CTE) that is to closely match the CTE of the glass. Singulated LED package structures including a plurality of LEDs arrayed for displays, such as, but not limited to, liquid crystal displays (LCDs) and LED displays or for general purpose LED light sources are described, as are LED package structures including active devices (e.g., ICs) and/or passive devices (e.g., capacitors, inductors, resistors, etc.) integrated with LEDs at the package level.

Abstract: Through substrate via (TSuV) structures and method of making the same are disclosed herein. In embodiments, TSuV structures are metal filled selectively to avoid forming significant metal overburden on non-via surfaces of the substrate. In certain embodiments, post-fill metal removal/planarization operations are eliminated for reduced process complexity and manufacturing cost. In embodiments, selective metal fill entails selective electroless or electrolytic deposition. Both front side and back side selective deposition methods are described along with features of through substrate via structures made with such methods.

Abstract: A copper electroplating bath composition and a method of copper electroplating to improve gapfill are provided. The method of electroplating includes providing an aqueous electroplating composition, comprising copper, at least one acid, at least one halogen ion, an additive including an accelerating agent, a suppressing agent, and a suppressing-accelerating agent, and the solution and mixture products thereof; contacting a substrate with the plating composition; and impressing a multi-step waveform potential upon the substrate, wherein the multi-step waveform potential includes an entry step, wherein the entry step includes a first sub-step applying a first current and a second sub-step applying second current, the second current being greater than the first current. The accelerating agent is provided in concentration of greater than 1.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include heating a substrate comprising a patterned metallic region to about 145 C or below in a reaction space, introducing an aluminum co-reactant into the reaction space, wherein an aluminum material is formed on the patterned metallic region, but not on non-metallic regions.

Abstract: Methods of forming a microelectronic structure are described. Embodiments of those methods include forming a barrier layer on a substrate, wherein the barrier layer comprises molybdenum; and forming a lead free interconnect structure on the barrier layer.

Abstract: Embodiments of methods in accordance with the present invention provide three-dimensional carbon nanotube (CNT) integrated circuits comprising layers of arrays of CNT's separated by dielectric layers with conductive traces formed within the dielectric layers to electrically interconnect individual CNT's. The methods to fabricate three-dimensional carbon nanotube FET integrated circuits include the selective deposition of carbon nanotubes onto catalysts selectively formed on a conductive layer at the bottom of openings in a dielectric layer. The openings in the dielectric layer are formed using suitable techniques, such as, but not limited to, dielectric etching, and the formation of ring gate electrodes, including spacers, that provide openings for depositing self-aligned carbon nanotube semiconductor channels.

Abstract: In one embodiment, an apparatus comprises a first layer having at least one interconnect formed in an interlayer dielectric (ILD), a second layer formed over the first layer having a second at least one interconnect, a third layer formed over the second layer, the third layer defining at least one air gap between the second at least one interconnect and the third layer, and at least one shunt selectively covering the first and second at least one interconnects. In another embodiment, a method comprises forming a first layer comprising an ILD and a first at least one interconnect, forming a second layer over the first layer, the second layer having a second at least one interconnect, depositing at least one shunt over the first and second at least one interconnects, forming a third layer over the second layer, and evaporating a portion of the second layer to create at least one air gap between the second at least one interconnect and the third layer.

Abstract: According to one aspect of the invention, a method of constructing an electronic assembly is provided. A layer of metal is formed on a backside of a semiconductor wafer having integrated formed thereon. Then, a porous layer is formed on the metal layer. A barrier layer of the porous layer at the bottom of the pores is thinned down. Then, a catalyst is deposited at the bottom of the pores. Carbon nanotubes are then grown in the pores. Another layer of metal is then formed over the porous layer and the carbon nanotubes. The semiconductor wafer is then separated into microelectronic dies. The dies are bonded to a semiconductor substrate, a heat spreader is placed on top of the die, and a semiconductor package resulting from such assembly is sealed. A thermal interface is formed on the top of the heat spreader. Then a heat sink is placed on top of the thermal interface.

Abstract: Noble metal may be used as a non-oxidizing diffusion barrier to prevent diffusion from copper lines. A diffusion barrier may be formed of a noble metal formed over an adhesion promoting layer or by a noble metal cap over an oxidizable diffusion barrier. The copper lines may also be covered with a noble metal.

Abstract: A device having a functionalized electrode having a probe molecule, wherein the device has an ability to electrically detect a molecular binding event between the probe molecule and a target molecule by a polarization change of the functionalized electrode is disclosed. The device could also include an unfunctionalized electrode that does not have the probe molecule and the device could have an ability to electrically detect the molecular binding event between the probe molecule and the target molecule by a polarization change between the functionalized electrode and the unfuctionalized electrode.

Abstract: In one embodiment, an apparatus comprises a first layer having at least one interconnect formed in an interlayer dielectric (ILD), a second layer formed over the first layer having a second at least one interconnect, a third layer formed over the second layer, the third layer defining at least one air gap between the second at least one interconnect and the third layer, and at least one shunt selectively covering the first and second at least one interconnects. In another embodiment, a method comprises forming a first layer comprising an ILD and a first at least one interconnect, forming a second layer over the first layer, the second layer having a second at least one interconnect, depositing at least one shunt over the first and second at least one interconnects, forming a third layer over the second layer, and evaporating a portion of the second layer to create at least one air gap between the second at least one interconnect and the third layer.

Abstract: A method comprising forming an interconnection opening through a dielectric material to a contact point; and electroplating a interconnection comprising copper in the contact opening using an electroplating bath comprising an alkoxylated sulfopropylated alkylamine. A method comprising forming an interconnection opening through a dielectric material to a contact point; lining the interconnection opening with a barrier layer and a seed layer; and electroplating an interconnection comprising copper in the contact opening using an electroplating bath comprising an alkoxylated sulfopropylated alkylamine.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming an opening in a substrate, placing at least one multi-walled CNT within the opening, and forming a carbide layer on the at least one multi-walled CNT.

Abstract: The invention provides bumps between a die and a substrate with a height greater than or equal to a height of a waveguide between the die and the substrate. The bumps may be formed on a die prior to that die being singulated from a wafer.

Abstract: Embodiments of the present invention provide methods for the fabrication of carbon nanotubes using composite metal films. A composite metal film is fabricated to provide uniform catalytic sites to facilitate the uniform growth of carbon nanotubes. Further embodiments provide embedded nanoparticles for carbon nanotube fabrication. Embodiments of the invention are capable of maintaining the integrity of the catalytic sites at temperatures used in carbon nanotube fabrication processes, 600 to 1100° C.

Abstract: A method including forming an interconnect of single-walled carbon nanotubes on a sacrificial substrate; transferring the interconnect from the sacrificial substrate to a circuit substrate; and coupling the interconnect to a contact point on the circuit substrate. A method including forming a nanotube bundle on a circuit substrate between a first contact point and a second contact point, the nanotube defining a lumen therethrough; filling a portion of a length of the lumen of the nanotube bundle with an electrically conductive material; and coupling the electrically conductive material to the second contact point. A system including a computing device comprising a microprocessor, the microprocessor coupled to a printed circuit board, the microprocessor including a substrate having a plurality of circuit devices with electrical connections made to the plurality of circuit devices through interconnect structures including carbon nanotube bundles.

Abstract: Methods of fabricating interconnect structures utilizing barrier material layers formed with an electroless deposition technique utilizing a coupling agent complexed with a catalytic metal and structures formed thereby. The fabrication fundamentally comprises providing a dielectric material layer having an opening extending into the dielectric material from a first surface thereof, bonding the coupling agent to the dielectric material within the opening, and electrolessly depositing the barrier material layer, wherein the electrolessly deposited barrier material layer material adheres to the catalytic metal of the coupling agent.