A method for replacement of solder balls of an electronic package soldered to seats located on a surface of the electronic package. The method comprises collectively heating the solder balls to melt the solder balls, removing each one of the solder balls from the corresponding seats by suction, providing a plurality of replacement solder balls, for each seat, positioning a corresponding one of the replacement solder balls on the respective seat to form an array of seated replacement solder balls, and collectively heating the array of seated replacement solder balls such that the replacement solder balls reflow and form metallurgical bonds with the seats. A system for replacing solder balls of an electronic package is also provided. An assembly for use in locating a plurality of solder balls onto an array of seats of an electronic package is also provided.

Apparatus for extending substrate queue time for hybrid bonding by preserving plasma activation. In some embodiments, the apparatus may include an environmentally controllable space with a support for holding a die or a substrate, a gas velocity accelerator that recirculates one or more gases laterally across the support, a filter, a humidifier apparatus that is fluidly connected to the environmentally controllable space, wherein the humidifier apparatus enables controllable humidity levels within the environmentally controllable space, a pressurizing apparatus fluidly connected to the humidifier apparatus on an output and fluidly connected to at least one gas supply on an input, a relative humidity (RH) sensor positioned within the environmentally controllable space, and an environment controller in communication with at least the humidifier apparatus and the RH sensor, wherein the environment controller is configured to maintain an RH level of approximately 80% to approximately 95%.

The present disclosure relates to systems and methods for fabricating semiconductor packages, and more particularly, for forming features in semiconductor packages by laser ablation. In one embodiment, the laser systems and methods described herein can be utilized to pattern a substrate to be utilized as a package frame for a semiconductor package having one or more interconnections formed therethrough and/or one or more semiconductor dies disposed therein. The laser systems described herein can produce tunable laser beams for forming features in a substrate or other package structure. Specifically, frequency, pulse width, pulse shape, and pulse energy of laser beams are tunable based on desired sizes of patterned features and on the material in which the patterned features are formed. The adjustability of the laser beams enables rapid and accurate formation of features in semiconductor substrates and packages with controlled depth and topography.

A method of fabrication a package and a stencil structure are provided. The stencil structure includes a first carrier having a groove and stencil units placed in the groove of the first carrier. At least one of the stencil units is slidably disposed along sidewalls of another stencil unit. Each of the stencil units has openings.

A jig for manufacturing a semiconductor package includes a bottom piece and an upper piece. The bottom piece includes a base, a support plate, and at least one elastic connector. The support plate is located in a central region of the base. The at least one elastic connector is interposed between the support plate and the base. The upper piece includes a cap and outer flanges. The cap overlays the support plate when the upper piece is disposed on the bottom piece. The outer flanges are disposed at edges of the cap, connected with the cap. The outer flanges contact the base of the bottom piece when the upper piece is disposed on the bottom piece. The cap includes an opening which is a through hole. When the upper piece is disposed on the bottom piece, a vertical projection of the opening falls entirely on the support plate.

A method of fabrication a package and a stencil structure are provided. The stencil structure includes a first carrier having a groove and stencil units placed in the groove of the first carrier. At least one of the stencil units is slidably disposed along sidewalls of another stencil unit. Each of the stencil units has openings.

A laser pressure head module including: a pressure member including: a first light-transmitting member; a second light-transmitting member; and a sealed space between the first light-transmitting member and the second light-transmitting member; and a gas supply unit to supply gas to the sealed space to generate a pressing force. The second light-transmitting member is to be expanded or moved in an external direction by the pressing force.

A jig for manufacturing a semiconductor package includes a bottom piece and an upper piece. The bottom piece includes a base, a support plate, and at least one elastic connector. The support plate is located in a central region of the base. The at least one elastic connector is interposed between the support plate and the base. The upper piece includes a cap and outer flanges. The cap overlays the support plate when the upper piece is disposed on the bottom piece. The outer flanges are disposed at edges of the cap, connected with the cap. The outer flanges contact the base of the bottom piece when the upper piece is disposed on the bottom piece. The cap includes an opening which is a through hole. When the upper piece is disposed on the bottom piece, a vertical projection of the opening falls entirely on the support plate.

A structural body is partially surrounded by a positioning plate, and a semiconductor element, a joining member, and a base plate around the joining member are exposed from the positioning plate, so that a positional relationship between the semiconductor element and the base plate is maintained. The joining member is heated by a heater while the semiconductor element, joining member, and base plate exposed from the positioning plate are isotropically pressurized by a piston via a medium and a bag member.

A method for replacement of solder balls of an electronic package soldered to seats located on a surface of the electronic package. The method comprises collectively heating the solder balls to melt the solder balls, removing each one of the solder balls from the corresponding seats by suction, providing a plurality of replacement solder balls, for each seat, positioning a corresponding one of the replacement solder balls on the respective seat to form an array of seated replacement solder balls, and collectively heating the array of seated replacement solder balls such that the replacement solder balls reflow and form metallurgical bonds with the seats. A system for replacing solder balls of an electronic package is also provided. An assembly for use in locating a plurality of solder balls onto an array of seats of an electronic package is also provided.