A cationically polymerizable anisotropic conductive film is provided. The cationically polymerizable anisotropic conductive film includes an alicyclic epoxy compound and achieves storage life property better than known anisotropic conductive films while ensuring curing temperature and connection reliability equivalent to known anisotropic conductive films. The anisotropic conductive film contains a binder composition containing a film forming component and a cationically polymerizable component, a cationic polymerization initiator, and conductive particles. The anisotropic conductive film contains a quaternary ammonium salt-based thermal acid generator as a cationic polymerization initiator and an alicyclic epoxy compound and a low polarity oxetane compound as a cationically polymerizable component.

A package includes a circuit that includes at least one active area and at least one secondary device area, a support configured to support the circuit, and a die attach material. The circuit being mounted on the support using the die attach material and the die attach material including at least one channel configured to allow gases generated during curing of the die attach material to be released from the die attach material.

A fabrication method of the device includes provision of a first stack including: a first substrate including at least one main surface provided with at least a first electric contact area, a second substrate provided with a salient spacer. The first substrate is assembled with the second substrate so as to define at least a first lateral groove including the first electric contact area, the first lateral groove being bounded by the first substrate, the second substrate and the spacer includes at least a first protuberance arranged to form a stop and to limit movement of the spacer relatively to the first substrate in at least a first direction passing via the first lateral groove and the spacer and a second direction parallel the longitudinal axis of the first groove and perpendicular to the first direction.

The carrier-foil-attached ultra-thin copper foil according to one embodiment of the present invention comprises a carrier foil, a release layer, a first ultra-thin copper foil, an Al layer, and a second ultra-thin copper foil, wherein the release layer may comprise a first metal (A1) having peeling properties, and a second metal (B1) and third metal (C1) facilitating the plating of the first metal (A1).

The carrier-foil-attached ultra-thin copper foil according to one embodiment of the present invention comprises a carrier foil, a release layer, a first ultra-thin copper foil, an Al layer, and a second ultra-thin copper foil, wherein the release layer may comprise a first metal (A1) having peeling properties, and a second metal (B1) and third metal (C1) facilitating the plating of the first metal (A1).

An electronic device made from the method of providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, laser bending the shaped metallic interconnects; and transferring the shaped metallic interconnects onto a receiving substrate or device.

A cationically polymerizable anisotropic conductive film is provided. The cationically polymerizable anisotropic conductive film includes an alicyclic epoxy compound and achieves storage life property better than known anisotropic conductive films while ensuring curing temperature and connection reliability equivalent to known anisotropic conductive films. The anisotropic conductive film contains a binder composition containing a film forming component and a cationically polymerizable component, a cationic polymerization initiator, and conductive particles. The anisotropic conductive film contains a quaternary ammonium salt-based thermal acid generator as a cationic polymerization initiator and an alicyclic epoxy compound and a low polarity oxetane compound as a cationically polymerizable component.

On the assumption that a pair of hanging parts is provided in a lead frame and a clip includes a main body part and a pair of extension parts, the pair of the extension parts is mounted and supported on the pair of the hanging parts. Accordingly, the clip is mounted on a lead (one point) and the pair of the hanging parts (two points), and the clip is supported by the three points.

On the assumption that a pair of hanging parts is provided in a lead frame and a clip includes a main body part and a pair of extension parts, the pair of the extension parts is mounted and supported on the pair of the hanging parts. Accordingly, the clip is mounted on a lead (one point) and the pair of the hanging parts (two points), and the clip is supported by the three points.

An electronic device made from the method of providing a donor substrate comprising an array of metallic interconnects, using a laser system to prepare the metallic interconnects, forming shaped metallic interconnects, laser bending the shaped metallic interconnects; and transferring the shaped metallic interconnects onto a receiving substrate or device.