The subject matter contained herein discloses methods for forming a vertical metallic pillar overlying an under bump metal pad further overlying a semiconductor substrate, and applying a discrete solder cap on a top surface of the pillar, wherein the metallic pillar is defined by at least one photoresist layer. The method includes heating a multi-element metallic paste containing a variable amount of metallic powder, a melting point depressant and a flux such that the metal powder sinters to form the metallic pillar and simultaneously adheres the metallic pillar to the underbump metal pad.

A power module package is provided, including a substrate, a first chip, and a second chip. The substrate includes a metal carrier, a patterned insulation layer disposed on the metal carrier and partially covering the metal carrier, and a patterned conductive layer disposed on the patterned insulation layer. The first chip is disposed on the metal carrier not covered by the patterned insulation layer. The second chip is disposed on the patterned conductive layer and electrically connected to the first chip.

An electric component comprising a terminal electrode and a hot-melt polymer layer formed on the terminal electrode, wherein the hot-melt polymer layer comprises (i) 100 parts by weight of a metal powder and (ii) 1 to 30 parts by weight of a polymer, wherein melt mass-flow rate (MFR) of the polymer is 0.5 to 20 g/10 min. at 120 to 200° C. and 0.3 to 8 kgf.

An embodiment of the invention discloses an optoelectronics system. The optoelectronic system includes an optoelectronic element having a first width; an adhesive material enclosing the optoelectronic element and having a second width larger than the first width; a phosphor structure formed between the optoelectronic element and the adhesive material; and a transparent substrate formed on the adhesive material.

There are provided a stacked type semiconductor device and a manufacturing method of the stacked type semiconductor device. The stacked type semiconductor device includes: semiconductor chips stacked to overlap with each other; through electrodes respectively penetrating the semiconductor chips, the through electrodes being bonded to each other; and empty gaps respectively buried in the through electrodes.

There are provided a stacked type semiconductor device and a manufacturing method of the stacked type semiconductor device. The stacked type semiconductor device includes: semiconductor chips stacked to overlap with each other; through electrodes respectively penetrating the semiconductor chips, the through electrodes being bonded to each other; and empty gaps respectively buried in the through electrodes.

An epoxy resin composition for encapsulating a semiconductor device and a semiconductor device encapsulated by the epoxy resin composition, the composition including a base resin; a filler; a colorant; and a thermochromic pigment, wherein a color of the thermochromic pigment is irreversibly changed when a temperature thereof exceeds a predetermined temperature.

In a method of manufacturing a semiconductor device of one embodiment, support members and a film which is formed of a paste containing metal particles and surrounds the support members are provided above a surface of a base. Then a semiconductor element is provided above the support members and the film. Subsequently, the film is sintered to join the base and the semiconductor element. The support members are formed of a metal which melts at a temperature equal to or below a sintering temperature of the metal particles contained in the paste. The support members support the semiconductor element after the semiconductor element is provided above the support members and the film.

In a method of manufacturing a semiconductor device of one embodiment, support members and a film which is formed of a paste containing metal particles and surrounds the support members are provided above a surface of a base. Then a semiconductor element is provided above the support members and the film. Subsequently, the film is sintered to join the base and the semiconductor element. The support members are formed of a metal which melts at a temperature equal to or below a sintering temperature of the metal particles contained in the paste. The support members support the semiconductor element after the semiconductor element is provided above the support members and the film.

The present invention is directed to a liquid and solid phase power connect for packaging of an electrical device using a using a phase changing metal. The phase changing metal transitions back and forth between a liquid phase and a solid phase while constantly maintaining connection to the electrical device. The packaging uses a substrate, a restraining housing, and a lid to encase an electrical contact on the electrical device and restrain the phase changing metal. In one embodiment, the entire electrical device is encased and a voltage isolator is utilized to limit the contact areas between the phase changing metal and the electrical device. A method for relieving contact stress by transitioning the phase changing metal from a solid to a liquid is also taught.