A semiconductor device includes a circuit substrate, a semiconductor package, connective terminals and supports. The circuit substrate has a first side and a second side opposite to the first side. The semiconductor package is connected to the first side of the circuit substrate. The connective terminals are located on the second side of the circuit substrate and are electrically connected to the semiconductor package via the circuit substrate. The supports are located on the second side of the circuit substrate beside the connective terminals. A material of the supports has a melting temperature higher than a melting temperature of the connective terminals.

Methods and apparatus to reduce defects in interconnects between semiconductor dies and package substrates are disclosed. An apparatus includes a substrate and a semiconductor die mounted to the substrate. The apparatus further includes bumps to electrically couple the die to the substrate. Ones of the bumps have corresponding bases. The bases have a shape that is non-circular.

Methods and apparatus to reduce defects in interconnects between semiconductor dies and package substrates are disclosed. An apparatus includes a substrate and a semiconductor die mounted to the substrate. The apparatus further includes bumps to electrically couple the die to the substrate. Ones of the bumps have corresponding bases. The bases have a shape that is non-circular.

An electronic device includes one or more multinode pads having two or more conductive segments spaced from one another on a semiconductor die. A conductive stud bump is selectively formed on portions of the first and second conductive segments to program circuitry of the semiconductor die or to couple a supply circuit to a load circuit. The multinode pad can be coupled to a programming circuit in the semiconductor die to allow programming a programmable circuit of the semiconductor die during packaging. The multinode pad has respective conductive segments coupled to the supply circuit and the load circuit to allow current consumption or other measurements during wafer probe testing in which the first and second conductive segments are separately probed prior to stud bump formation.

An electronic device includes one or more multinode pads having two or more conductive segments spaced from one another on a semiconductor die. A conductive stud bump is selectively formed on portions of the first and second conductive segments to program circuitry of the semiconductor die or to couple a supply circuit to a load circuit. The multinode pad can be coupled to a programming circuit in the semiconductor die to allow programming a programmable circuit of the semiconductor die during packaging. The multinode pad has respective conductive segments coupled to the supply circuit and the load circuit to allow current consumption or other measurements during wafer probe testing in which the first and second conductive segments are separately probed prior to stud bump formation.

A method of preparing a semiconductor substrate with metal bumps on both sides of the substrate. The method includes depositing a first-side UBM layer on a first surface of the semiconductor substrate. The method includes forming a plurality of first-side metal bumps on the first surface of the semiconductor substrate after the first-side UBM layer is deposited. The method includes forming a second-side UBM layer on a second side of the semiconductor substrate. The method includes forming a plurality of second-side metal bumps on the second surface of the semiconductor substrate after the second-side UBM layer is deposited. The method includes removing exposed first-side UBM layer and exposed second-side UBM layer after the plurality of first-side metal bumps and the plurality of second-side metal bumps are formed. The method includes reflowing the plurality of first-side metal bumps and the plurality of second side metal bumps.

A method of preparing a semiconductor substrate with metal bumps on both sides of the substrate. The method includes depositing a first-side UBM layer on a first surface of the semiconductor substrate. The method includes forming a plurality of first-side metal bumps on the first surface of the semiconductor substrate after the first-side UBM layer is deposited. The method includes forming a second-side UBM layer on a second side of the semiconductor substrate. The method includes forming a plurality of second-side metal bumps on the second surface of the semiconductor substrate after the second-side UBM layer is deposited. The method includes removing exposed first-side UBM layer and exposed second-side UBM layer after the plurality of first-side metal bumps and the plurality of second-side metal bumps are formed. The method includes reflowing the plurality of first-side metal bumps and the plurality of second side metal bumps.

A semiconductor device includes a semiconductor substrate divided into a pad region and a cell region and having an active surface and an inactive surface opposite to the active surface, a plurality of metal lines on the active surface of the semiconductor substrate, passivation layers on the active surface of the semiconductor substrate, and a plurality of bumps in the cell region. The passivation layers include a first passivation layer covering the plurality of metal lines and having a non-planarized top surface along an arrangement profile of the plurality of metal lines, and a second passivation layer on the non-planarized top surface of the first passivation layer and having a planarized top surface on which the plurality of bumps are disposed.

A semiconductor device includes a semiconductor substrate divided into a pad region and a cell region and having an active surface and an inactive surface opposite to the active surface, a plurality of metal lines on the active surface of the semiconductor substrate, passivation layers on the active surface of the semiconductor substrate, and a plurality of bumps in the cell region. The passivation layers include a first passivation layer covering the plurality of metal lines and having a non-planarized top surface along an arrangement profile of the plurality of metal lines, and a second passivation layer on the non-planarized top surface of the first passivation layer and having a planarized top surface on which the plurality of bumps are disposed.

The present disclosure provides a semiconductor structure and a manufacturing method thereof. The semiconductor structure includes a first chip and a second chip. A first conductive connection wire of the first chip is connected to a first conductive contact pad, and a second conductive connection wire of the second chip is connected to a second conductive contact pad. In addition, the first conductive contact pad includes a first conductor and a second conductor, and the second conductive contact pad includes a third conductor and a fourth conductor. The first conductor is directly opposite to the fourth conductor, and the second conductor is directly opposite to the third conductor. Therefore, pre-connection of the first conductive contact pad and the second conductive contact pad may be implemented and then the first chip and second chip that are pre-connected are transferred for bonding.