Abstract: 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.

Abstract: 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.

Abstract: Methods are disclosed for forming flat no-leads packages (e.g., QFN packages) with soldering surfaces that are fully coated, e.g., by a tin immersion process, for improved solder connections of the packages to a PCB or other structure. The method includes forming a flat no-leads package structure including a leadframe terminal structure having an exposed top or bottom surface; forming a first coating of a first coating material (e.g., tin) on the exposed top or bottom surface; cutting through a full thickness of the leadframe terminal structure to define an exposed terminal sidewall surface; and forming a second coating of a second coating material (e.g., tin) over the full height of the exposed terminal sidewall surface. The coating (e.g., tin immersion coating) covering the full height of the leadframe terminal sidewall may enhance the flow of solder material, e.g., when soldering to a PCB, to provide an improved solder connection.

Abstract: Methods are disclosed for forming flat leads packages (e.g., QFP or SOT packages) having leads coated with a solder-enhancing material for improved solder mounting to a PCB or other structure. The method may include forming a flat leads package structure including an array of encapsulated IC structures formed on a common leadframe. An isolation cutting process may be performed to electrically isolate the IC structures from each other and define a plurality of leadframe leads extending from each IC structure. After the isolation cutting process, an immersion coating process is performed to coat exposed surfaces of the leadframe leads, including the full surface area of a distal end of each leadframe lead. The coating (e.g., tin coating) covering the distal ends of the leadframe leads may enhance the flow of solder material, e.g., when soldering to a PCB, to provide an improved solder connection.

Abstract: Methods are disclosed for forming flat leads packages (e.g., QFP or SOT packages) having leads coated with a solder-enhancing material for improved solder mounting to a PCB or other structure. The method may include forming a flat leads package structure including an array of encapsulated IC structures formed on a common leadframe. An isolation cutting process may be performed to electrically isolate the IC structures from each other and define a plurality of leadframe leads extending from each IC structure. After the isolation cutting process, an immersion coating process is performed to coat exposed surfaces of the leadframe leads, including the full surface area of a distal end of each leadframe lead. The coating (e.g., tin coating) covering the distal ends of the leadframe leads may enhance the flow of solder material, e.g., when soldering to a PCB, to provide an improved solder connection.

Abstract: Methods are disclosed for forming flat no-leads packages (e.g., QFN packages) with soldering surfaces that are fully coated, e.g., by a tin immersion process, for improved solder connections of the packages to a PCB or other structure. The method includes forming a flat no-leads package structure including a leadframe terminal structure having an exposed top or bottom surface; forming a first coating of a first coating material (e.g., tin) on the exposed top or bottom surface; cutting through a full thickness of the leadframe terminal structure to define an exposed terminal sidewall surface; and forming a second coating of a second coating material (e.g., tin) over the full height of the exposed terminal sidewall surface. The coating (e.g., tin immersion coating) covering the full height of the leadframe terminal sidewall may enhance the flow of solder material, e.g., when soldering to a PCB, to provide an improved solder connection.

Abstract: According to an embodiment of the present disclosure, a method for manufacturing an integrated circuit (IC) device may include mounting an IC chip onto a center support structure of a leadframe. The leadframe may include: a plurality of pins extending from the center support structure; a groove running perpendicular to the individual pins of the plurality of pins around the center support structure; and a bar connecting the plurality of pins remote from the center support structure.