An integrated circuit die may be fabricating to have a plurality of contacts. A metal post may be formed on each of the plurality of contacts. A plurality of bumps may be formed on a plurality of contact regions of a leadframe or on the posts, in which the plurality of bumps are formed with a material that includes metal nanoparticles. The IC die may be attached to the leadframe by aligning the metal posts to the leadframe and sintering the metal nanoparticles in the plurality of bumps to form a sintered metal bond between each metal post and corresponding contact region of the leadframe.

Introducing an underfill material over contact pads on a surface of an integrated circuit substrate; and ablating the introduced underfill material to expose an area of the contact pads using temporally coherent electromagnetic radiation. A method including first ablating an underfill material to expose an area of contact pads on a substrate using temporally coherent electromagnetic radiation; introducing a solder to the exposed area of the contact pads; and second ablating the underfill material using temporally coherent electromagnetic radiation. A method including introducing an underfill material over contact pads on a surface of an integrated circuit substrate; defining an opening in the underfill material to expose an area of the contact pads using temporally coherent electromagnetic radiation; introducing a solder material to the exposed area of the contact pads; and after introducing the solder, removing the sacrificial material.

Introducing an underfill material over contact pads on a surface of an integrated circuit substrate; and ablating the introduced underfill material to expose an area of the contact pads using temporally coherent electromagnetic radiation. A method including first ablating an underfill material to expose an area of contact pads on a substrate using temporally coherent electromagnetic radiation; introducing a solder to the exposed area of the contact pads; and second ablating the underfill material using temporally coherent electromagnetic radiation. A method including introducing an underfill material over contact pads on a surface of an integrated circuit substrate; defining an opening in the underfill material to expose an area of the contact pads using temporally coherent electromagnetic radiation; introducing a solder material to the exposed area of the contact pads; and after introducing the solder, removing the sacrificial material.

A one-step water soluble (WS) flux process may reduce residue staining and increase yields for bond grid array (BGA) packages. In one example, the WS flux may use increased amounts of bonding polymer (BP) and reduced amounts of amine to increase viscosity. The increased viscosity may eliminate using a second no-clean flux and enable a single WS flux to both clean the associated substrate and provide stable solder ball support during reflow.

A one-step water soluble (WS) flux process may reduce residue staining and increase yields for bond grid array (BGA) packages. In one example, the WS flux may use increased amounts of bonding polymer (BP) and reduced amounts of amine to increase viscosity. The increased viscosity may eliminate using a second no-clean flux and enable a single WS flux to both clean the associated substrate and provide stable solder ball support during reflow.

To improve reliability of a semiconductor device, in a method of manufacturing the semiconductor device, a semiconductor substrate having an insulating film in which an opening that exposes each of a plurality of electrode pads is formed is provided, and a flux member including conductive particles is arranged over each of the electrode pads. Thereafter, a solder ball is arranged over each of the electrode pads via the flux member, and is then heated via the flux member so that the solder ball is bonded to each of the electrode pads. The width of the opening of the insulating film is smaller than the width (diameter) of the solder ball.

Dense interconnect with solder cap (DISC) formation with laser ablation and resulting semiconductor structures and packages are described. For example, a method of fabricating a semiconductor structure includes forming an insulative material stack above a plurality of solder bump landing pads. The solder bump landing pads are above an active side of a semiconductor die. A plurality of trenches is formed in the insulative material stack by laser ablation to expose a corresponding portion of each of the plurality of solder bump landing pads. A solder bump is formed in each of the plurality of trenches. A portion of the insulative material stack is then removed.

Embodiments of the present disclosure include semiconductor packages and methods of forming the same. An embodiment is a semiconductor package including a first package including one or more dies, and a redistribution layer coupled to the one or more dies at a first side of the first package with a first set of bonding joints. The redistribution layer including more than one metal layer disposed in more than one passivation layer, the first set of bonding joints being directly coupled to at least one of the one or more metal layers, and a first set of connectors coupled to a second side of the redistribution layer, the second side being opposite the first side.

Embodiments of the present disclosure include semiconductor packages and methods of forming the same. An embodiment is a semiconductor package including a first package including one or more dies, and a redistribution layer coupled to the one or more dies at a first side of the first package with a first set of bonding joints. The redistribution layer including more than one metal layer disposed in more than one passivation layer, the first set of bonding joints being directly coupled to at least one of the one or more metal layers, and a first set of connectors coupled to a second side of the redistribution layer, the second side being opposite the first side.

Embodiments herein may relate to a solder paste. The solder paste may include a solder powder and a flux. In embodiments, the flux may be a non-rosin based flux. The flux may further include a thixotropic agent (TA) that may be a non-polymer based TA. Other embodiments may be described and/or claimed.