A semiconductor package device includes a carrier, a first electronic component, and a conductive element on the carrier. The first electronic component is over the carrier. The conductive element is on the carrier and electrically connects the first electronic component to the carrier. The conductive element includes at least one conductive particle and a solder material covering the conductive particle, and the conductive particle includes a metal core, a barrier layer covering the metal core, and a metal layer covering the barrier layer.

A method forming an interconnect structure includes depositing a first solder bump on a chip; depositing a second solder bump on a laminate, the second solder bump including a nickel copper colloid surrounded by a nickel or copper shell and suspended in a tin-based solder; aligning the chip with the laminate; performing a first reflow process to join the chip to the laminate; depositing an underfill material around the first solder bump and the second solder bump; and performing a second reflow process at a temperature that is lower than the first reflow process to convert the first solder bump and the second solder bump to an all intermetallic interconnect; wherein depositing the underfill material is performed before or after performing the second reflow process.

A method forming an interconnect structure includes depositing a first solder bump on a chip; depositing a second solder bump on a laminate, the second solder bump including a nickel copper colloid surrounded by a nickel or copper shell and suspended in a tin-based solder; aligning the chip with the laminate; performing a first reflow process to join the chip to the laminate; depositing an underfill material around the first solder bump and the second solder bump; and performing a second reflow process at a temperature that is lower than the first reflow process to convert the first solder bump and the second solder bump to an all intermetallic interconnect; wherein depositing the underfill material is performed before or after performing the second reflow process.

An electro-conductive paste includes a metal particle and a vehicle in which the metal particle is dispersed. The metal particle has a particle size in a range from 1 m to 20 m and consists of an outer shell and a core part. The core part contains Sn or a Sn alloy. The outer shell contains an intermetallic compound of Sn and Cu and covers 50% or more of a total surface area of the core part.

A formed article includes a metal particle which has a particle size in a range from 1 m to 20 m and consists of an outer shell and a core part. The core part contains Sn or a Sn alloy. The outer shell contains an intermetallic compound of Sn and Cu and covers 50% or more of a total surface area of the core part.

Aiming at providing a metal particle, an electro-conductive paste, a formed article, and a laminated article that are able to form a highly reliable and high-quality electric interconnect, an electro-conductive bonding portion, or a three-dimensional structure that is less likely to produce the Kirkendall void, this invention discloses a metal particle which include an outer shell and a core part, the outer shell including an intermetallic compound and covering the core part.

A method forming an interconnect structure includes depositing a first solder bump on a chip; depositing a second solder bump on a laminate, the second solder bump including a nickel copper colloid surrounded by a nickel or copper shell and suspended in a tin-based solder; aligning the chip with the laminate; performing a first reflow process to join the chip to the laminate; depositing an underfill material around the first solder bump and the second solder bump; and performing a second reflow process at a temperature that is lower than the first reflow process to convert the first solder bump and the second solder bump to an all intermetallic interconnect; wherein depositing the underfill material is performed before or after performing the second reflow process.

A method forming an interconnect structure includes depositing a first solder bump on a chip; depositing a second solder bump on a laminate, the second solder bump including a nickel copper colloid surrounded by a nickel or copper shell and suspended in a tin-based solder; aligning the chip with the laminate; performing a first reflow process to join the chip to the laminate; depositing an underfill material around the first solder bump and the second solder bump; and performing a second reflow process at a temperature that is lower than the first reflow process to convert the first solder bump and the second solder bump to an all intermetallic interconnect; wherein depositing the underfill material is performed before or after performing the second reflow process.

A method forming an interconnect structure includes depositing a first solder bump on a chip; depositing a second solder bump on a laminate, the second solder bump including a nickel copper colloid surrounded by a nickel or copper shell and suspended in a tin-based solder; aligning the chip with the laminate; performing a first reflow process to join the chip to the laminate; depositing an underfill material around the first solder bump and the second solder bump; and performing a second reflow process at a temperature that is lower than the first reflow process to convert the first solder bump and the second solder bump to an all intermetallic interconnect; wherein depositing the underfill material is performed before or after performing the second reflow process.

A method forming an interconnect structure includes depositing a first solder bump on a chip; depositing a second solder bump on a laminate, the second solder bump including a nickel copper colloid surrounded by a nickel or copper shell and suspended in a tin-based solder; aligning the chip with the laminate; performing a first reflow process to join the chip to the laminate; depositing an underfill material around the first solder bump and the second solder bump; and performing a second reflow process at a temperature that is lower than the first reflow process to convert the first solder bump and the second solder bump to an all intermetallic interconnect; wherein depositing the underfill material is performed before or after performing the second reflow process.