A method for forming a chip package structure is provided. The method includes bonding a chip to a first surface of a first substrate. The method includes forming a bump and a dummy bump over a second surface of the first substrate. The dummy bump is close to a first corner of the first substrate, and the dummy bump is wider than the bump. The method includes bonding the first substrate to a second substrate through the bump. The dummy bump is electrically insulated from the chip and the second substrate. The method includes forming a protective layer between the first substrate and the second substrate. The protective layer surrounds the dummy bump and the bump, and the protective layer is between the dummy bump and the second substrate.

A method for forming a chip package structure is provided. The method includes bonding a chip to a first surface of a first substrate. The method includes forming a dummy bump over a second surface of the first substrate. The first surface is opposite the second surface, and the dummy bump is electrically insulated from the chip. The method includes cutting through the first substrate and the dummy bump to form a cut substrate and a cut dummy bump. The cut dummy bump is over a corner portion of the cut substrate, a first sidewall of the cut dummy bump is substantially coplanar with a second sidewall of the cut substrate, and a third sidewall of the cut dummy bump is substantially coplanar with a fourth sidewall of the cut substrate.

A method for forming a chip package structure is provided. The method includes bonding a chip to a first surface of a first substrate. The method includes forming a bump and a dummy bump over a second surface of the first substrate. The dummy bump is close to a first corner of the first substrate, and the dummy bump is wider than the bump. The method includes bonding the first substrate to a second substrate through the bump. The dummy bump is electrically insulated from the chip and the second substrate. The method includes forming a protective layer between the first substrate and the second substrate. The protective layer surrounds the dummy bump and the bump, and the protective layer is between the dummy bump and the second substrate.

Provided is an electroconductive adhesive which is less apt to suffer cracking, chipping, etc. upon sintering and gives sintered objects having excellent mechanical strength. The electroconductive adhesive comprises metallic microparticles which include a protective layer comprising one or more amines and have an average particle diameter of 30-300 nm, the amines comprising a C.sub.5-7 monoalkylamine and/or an alkoxyamine represented by the following general formula (1). NH.sub.2R.sup.2OR.sup.1 (1) In the protective layer, the ratio of the C.sub.5-7 monoalkylamine and/or alkoxyamine represented by the general formula (1) to one or more amines different therefrom is in the range of 100:0 to 10:90. [In formula (1), R.sup.1 represents a C.sub.1-4 alkyl group and R.sup.2 represents a C.sub.1-4 alkylene group.]

In order to prevent cracks from occurring at the corners of semiconductor dies after the semiconductor dies have been bonded to other substrates, an opening is formed adjacent to the corners of the semiconductor dies, and the openings are filled and overfilled with a buffer material that has physical properties that are between the physical properties of the semiconductor die and an underfill material that is placed adjacent to the buffer material.

In order to prevent cracks from occurring at the corners of semiconductor dies after the semiconductor dies have been bonded to other substrates, an opening is formed adjacent to the corners of the semiconductor dies, and the openings are filled and overfilled with a buffer material that has physical properties that are between the physical properties of the semiconductor die and an underfill material that is placed adjacent to the buffer material.

A package that includes a first integrated device comprising a first plurality of interconnects; a plurality of solder interconnects coupled to the first plurality of interconnects; a second integrated device comprising a second plurality of interconnects, wherein the second integrated device is coupled to the first integrated device through the second plurality of interconnects, the plurality of solder interconnects and the first plurality of interconnects; a polymer layer located between the first integrated device and the second integrated device; and a plurality of spacer balls located between the first integrated device and the second integrated device.

An integrated circuit package includes at least one electronic chip having a first face fastened onto a first face of a carrier substrate by an adhesive interface. The adhesive interface includes a crown formed of a first adhesive material that is fastened on the periphery of the first face of the electronic chip. The crown defining an internal housing. A second adhesive material, different than the first material, is deposited in the internal housing.

A semiconductor device includes: a substrate; a semiconductor chip disposed adjacent to a front surface of the semiconductor substrate; an adhesive fixing a back surface of the semiconductor chip to the front surface of the substrate; and a plurality of spacers disposed to regulate a distance between the substrate and the semiconductor chip. The spacers are bonded to the front surface of the substrate or the back surface of the semiconductor chip, and are located on respective vertexes of a polygon surrounding a center of gravity of the semiconductor chip.

A semiconductor device and method of manufacturing is provided, whereby a support structure is utilized to provide additional support for a conductive element in order to eliminate or reduce the formation of a defective surface such that the conductive element may be formed to have a thinner structure without suffering deleterious structures.