Edge interconnects for interconnecting solar cells are disclosed. The edge interconnects include a layer of an electrically conductive adhesive overlying an insulating dielectric layer applied to edge of a solar cell and electrically interconnected to a busbar. Solar cell modules include adjacent solar cells comprising edge interconnects interconnected using an interconnection element. An interconnection element can be a solder paste or a solder containing electrically conductive ribbon. Methods of forming solar cell edge interconnects include applying an insulating dielectric coating to edges of a solar cell, depositing a busbar in proximity to the insulated edges of the solar cell, depositing an electrically conductive adhesive over at least portion of the busbar an over at least a portion of the dielectric layer. Solar cell modules can be formed by interconnecting adjacent solar cells using an interconnection element.

The present disclosure relates to methods and apparatus for forming a thin-form-factor semiconductor package. In one embodiment, a glass or silicon substrate is structured by micro-blasting or laser ablation to form structures for formation of interconnections therethrough. The substrate is thereafter utilized as a frame for forming a semiconductor package with embedded dies therein.

The present disclosure relates to methods and apparatus for forming a thin-form-factor semiconductor package. In one embodiment, a glass or silicon substrate is structured by micro-blasting or laser ablation to form structures for formation of interconnections therethrough. The substrate is thereafter utilized as a frame for forming a semiconductor package with embedded dies therein.

The present disclosure relates to methods and apparatus for forming thin-form-factor reconstituted substrates and semiconductor device packages for radio frequency applications. The substrate and package structures described herein may be utilized in high-density 2D and 3D integrated devices for 4G, 5G, 6G, and other wireless network systems. In one embodiment, a silicon substrate is structured by laser ablation to include cavities for placement of semiconductor dies and vias for deposition of conductive interconnections. Additionally, one or more cavities are structured to be filled or occupied with a flowable dielectric material. Integration of one or more radio frequency components adjacent the dielectric-filled cavities enables improved performance of the radio frequency elements with reduced signal loss caused by the silicon substrate.

The present invention relates to a process of a surface-mounting three-dimensional package structure electrically connected by a pre-packaged metal, comprising: taking a metal sheet; punching or etching the metal sheet; packaging a conductive metal-pillar frame; performing windowing and slotting; taking a substrate on which a chip is surface-mounted; fitting the conductive metal-pillar frame; performing packaging and grinding; surface-mounting a passive device; performing plastic packaging and ball-mounting; and performing cutting. The process of the present invention can improve the integration level and the reliability.

Edge interconnects for interconnecting solar cells are disclosed. The edge interconnects include a layer of an electrically conductive adhesive overlying an insulating dielectric layer applied to edge of a solar cell and electrically interconnected to a busbar. Solar cell modules include adjacent solar cells comprising edge interconnects interconnected using an interconnection element. An interconnection element can be a solder paste or a solder containing electrically conductive ribbon. Methods of forming solar cell edge interconnects include applying an insulating dielectric coating to edges of a solar cell, depositing a busbar in proximity to the insulated edges of the solar cell, depositing an electrically conductive adhesive over at least portion of the busbar an over at least a portion of the dielectric layer. Solar cell modules can be formed by interconnecting adjacent solar cells using an interconnection element.

The present disclosure relates to thin-form-factor reconstituted substrates and methods for forming the same. The reconstituted substrates described herein may be utilized to fabricate homogeneous or heterogeneous high-density 3D integrated devices. In one embodiment, a silicon substrate is structured by direct laser patterning to include one or more cavities and one or more vias. One or more semiconductor dies of the same or different types may be placed within the cavities and thereafter embedded in the substrate upon formation of an insulating layer thereon. One or more conductive interconnections are formed in the vias and may have contact points redistributed to desired surfaces of the reconstituted substrate. The reconstituted substrate may thereafter be integrated into a stacked 3D device.

Disclosed is a probe bonding device and method. The probe bonding device includes, a second gripper configured to move the probe to a bonding position on the substrate, a laser unit configured to emit a laser beam, a fourth vision device configured to check whether the probe gripped by the second gripper; and a controller configured to control the second gripper and the fourth vision device, wherein the controller controls the fourth vision device to photograph one end of the probe a plurality of numbers of times while sequentially adjusting a height of at least one of the second gripper and the fourth vision device at a predetermined interval to acquire information on a height of the probe based on a plurality of captured images, thereby bonding the probe to an accurate position to enhance bonding quality of the probe and quality of a probe card.

Edge interconnects for interconnecting solar cells are disclosed. The edge interconnects include a layer of an electrically conductive adhesive overlying an insulating dielectric layer applied to edge of a solar cell and electrically interconnected to a busbar. Solar cell modules include adjacent solar cells comprising edge interconnects interconnected using an interconnection element. An interconnection element can be a solder paste or a solder containing electrically conductive ribbon. Methods of forming solar cell edge interconnects include applying an insulating dielectric coating to edges of a solar cell, depositing a busbar in proximity to the insulated edges of the solar cell, depositing an electrically conductive adhesive over at least portion of the busbar an over at least a portion of the dielectric layer. Solar cell modules can be formed by interconnecting adjacent solar cells using an interconnection element.

Flat no-leads integrated circuit (IC) packages are formed with solder wettable leadframe terminals. Dies are mounted on die attach pads, bonded to adjacent leadframe terminal structures, and encapsulated in a mold compound. A laser grooving process removes mold compound from a leadframe terminal groove extending along a row of leadframe terminal structures. A saw step cut along the leadframe terminal groove extends partially through the leadframe thickness to define a saw step cut groove. Exposed leadframe surfaces, including surfaces exposed by the saw step cut, are plated with a solder-enhancing material. A singulation cut is performed along the saw step cut groove to define leadframe terminals with end surfaces plated with the solder-enhancing material. The laser grooving process may improve the results of the saw step cut, and the saw step cut may remove mold compound not removed by the laser grooving process.