Abstract: A fan-out packaging method includes: prepare circuit patterns on one side or both sides of a substrate; install electronic parts on one side or both sides of the substrate; prepare packaging layers on both sides of the substrate; the packaging layers on both sides of the substrate package the substrate, the circuit patterns, and the electronic parts, the packaging layers being made of a thermal-plastic material; wherein the substrate is provided with a via hole; both sides of the substrate are communicated by means of the via hole; a part of the packaging layers penetrate through the via hole when the packaging layers are prepared on both sides of the substrate; and the packaging layers on both sides of the substrate are connected by means of the via hole.

Abstract: A fan-out packaging method includes: prepare circuit patterns on one side or both sides of a substrate; install electronic parts on one side or both sides of the substrate; prepare packaging layers on both sides of the substrate; the packaging layers on both sides of the substrate package the substrate, the circuit patterns, and the electronic parts, the packaging layers being made of a thermal-plastic material; wherein the substrate is provided with a via hole; both sides of the substrate are communicated by means of the via hole; a part of the packaging layers penetrate through the via hole when the packaging layers are prepared on both sides of the substrate; and the packaging layers on both sides of the substrate are connected by means of the via hole.

Abstract: This disclosure relates generally to generating a solder-on-die using a water-soluble resist, system, and method. Heat may be applied to solder as applied to a hole formed in a water-soluble resist coating, the water-soluble resist coating being on a surface of an initial assembly. The initial assembly may include an electronic component. The surface may be formed, at least in part, by an electrical terminal of the electronic component, the hole being aligned, at least in part, with the electrical terminal. The solder may be reflowed, wherein the solder couples, at least in part, with the electrical terminal.

Abstract: This disclosure relates generally to generating a solder-on-die using a water-soluble resist, system, and method. Heat may be applied to solder as applied to a hole formed in a water-soluble resist coating, the water-soluble resist coating being on a surface of an initial assembly. The initial assembly may include an electronic component. The surface may be formed, at least in part, by an electrical terminal of the electronic component, the hole being aligned, at least in part, with the electrical terminal. The solder may be reflowed, wherein the solder couples, at least in part, with the electrical terminal.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: Embodiments of an apparatus and methods of forming a package on package interconnect and its application to the packaging of microelectronic devices are described herein. Other embodiments may be described and claimed.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: Embodiments of an apparatus and methods of forming a package on package interconnect and its application to the packaging of microelectronic devices are described herein. Other embodiments may be described and claimed.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: A capacitor may be formed of carbon nanotubes. Carbon nanotubes, grown on substrates, may be formed in a desired pattern. The pattern may be defined by placing catalyst in appropriate locations for carbon nanotube growth from a substrate. Then, intermeshing arrays of carbon nanotubes may be formed by juxtaposing the carbon nanotubes formed on opposed substrates. In some embodiments, the carbon nanotubes may be covered by a dielectric which may be adhered by functionalizing the carbon nanotubes.

Abstract: A carbon nanotube (CNT) array is patterned on a substrate. The substrate can be a microelectronic die or a heat sink for a die. The patterned CNT array is patterned by using a patterned catalyst on the substrate to form the CNT array by growing. The patterned CNT array can also be patterned by using a patterned mask on the substrate to form the CNT array by growing. A computing system that uses the CNT array for heat transfer from the die is also used.

Abstract: In some embodiments, an adhesive system for supporting thin silicon wafer is presented. In this regard, a method is introduced to bond a silicon wafer to a translucent carrier through the use of an adhesive. Other embodiments are also disclosed and claimed.

Abstract: A method of supporting a microelectronic wafer during backside processing. The method comprises: selecting a rigid carrier including a radiation absorbing film thereon, an adhesive, and a radiation source to emit radiation at a predetermined wavelength range; forming a wafer-carrier stack by providing the adhesive between the wafer and the carrier and curing the adhesive to bond the wafer to the carrier; subjecting the wafer in the wafer-carrier stack to backside processing; and removing the carrier and the adhesive from the wafer-carrier stack comprising detackifying the adhesive by irradiating the wafer-carrier stack from a carrier side thereof with radiation from the radiation source. The carrier is adapted to transmit therethrough at least some of the radiation from the radiation source.

Abstract: A system, apparatus and method of using an adhesive substrate capable of maintaining adhesion between a carrier and a work piece during a thinning process and then withstanding processing temperatures equal to or in excess of 160 degrees Celsius and with subsequent removal of the carrier and the adhesive substrate without solvent are described herein.

Abstract: A method of supporting a microelectronic wafer during backside processing. The method comprises: selecting a rigid carrier, an adhesive, and a radiation source to emit radiation at a predetermined wavelength range; forming a wafer-carrier stack by providing the adhesive between the wafer and the carrier and curing the adhesive to bond the wafer to the carrier; subjecting the wafer in the wafer-carrier stack to backside processing; and removing the carrier and the adhesive from the wafer-carrier stack comprising detackifying the adhesive by irradiating the wafer-carrier stack from a carrier side thereof with radiation from the radiation source. The carrier is adapted to transmit therethrough at least some of the radiation from the radiation source. and the adhesive is adapted to absorb substantially all radiation transmitted through the carrier and is further adapted to be detackified as a result of absorbing said substantially all radiation.

Abstract: Some embodiments of the present invention include locking mechanisms for die assembly.

Abstract: A circuit device (15) is placed within an opening of a conductive layer (10) which is then partially encapsulated with an encapsulant (24) so that the active surface of the circuit device (15) is coplanar with the conductive layer (10). At least a portion of the conductive layer (10) may be used as a reference voltage plane (e.g. a ground plane). Additionally, a circuit device (115) may be placed on a conductive layer (100) such that an active surface of circuit device (115) is between conductive layer (100) and an opposite surface of circuit device (115). The conductive layer (100) has at least one opening (128) to expose the active surface of circuit device (115). The encapsulant (24, 126, 326) may be electrically conductive or electrically non-conductive.