A method for transferring a micro device, includes: a compression step in which a carrier film having a micro-device attached to an adhesive layer thereof is brought into contact with a substrate comprising a solder deposited on metal electrodes formed on the substrate and is compressed on the substrate; a first adhesive strength generation step in which the solder disposed between the micro-device and the metal electrodes is compressed in the compression step to generate first adhesive strength between the micro-device and the solder; a second adhesive generation step in which the micro-device is bonded to the adhesive layer through press-fitting in the compression step to generate second adhesive strength between the micro-device and the adhesive layer; and a release step in which the carrier film is separated from the substrate, with the micro-device adhered to the solder.

A light-emitting module includes a common carrier; a plurality of semiconductor devices formed on the common carrier, and each of the plurality of semiconductor devices including three semiconductor dies; a carrier including a connecting surface; a third bonding pad and a fourth bonding pad formed on the connecting surface; and a connecting layer. One of the three semiconductor dies includes a stacking structure; a first bonding pad; and a second bonding pad with a shortest distance less than 150 microns between the first bonding pad. The connecting layer includes a first conductive part including a first conductive material having a first shape; and a blocking part covering the first conductive part and including a second conductive material having a second shape with a diameter in a cross-sectional view. The first shape has a height greater than the diameter.

A method of manufacturing a multi-layer wafer is provided. At least one stress compensating polymer layer is applied to at least one of two heterogeneous wafers. The stress compensating polymer layer is low temperature bonded to the other of the two heterogeneous wafers to form a multi-layer wafer pair. Channels are created between die on at least one of the two heterogeneous wafers. The channels are back filled with one of oxide or polymer to create a channel oxide deposition.

A method of manufacturing a multi-layer wafer is provided. At least one stress compensating polymer layer is applied to at least one of two heterogeneous wafers. The stress compensating polymer layer is low temperature bonded to the other of the two heterogeneous wafers to form a multi-layer wafer pair. Channels are created between die on at least one of the two heterogeneous wafers. The channels are back filled with one of oxide or polymer to create a channel oxide deposition.

Provided is a method of fabricating a semiconductor package. The method includes preparing a package substrate having a substrate pad, and mounting a semiconductor chip on the substrate pad. Mounting the semiconductor chip includes forming a resin layer containing a solder and reducing agent granules having a first capsule layer, between a chip pad of the semiconductor chip and the substrate pad, and bonding the chip pad to the substrate pad using laser irradiated to the semiconductor chip.

Provided is a method of fabricating a semiconductor package. The method includes preparing a package substrate having a substrate pad, and mounting a semiconductor chip on the substrate pad. Mounting the semiconductor chip includes forming a resin layer containing a solder and reducing agent granules having a first capsule layer, between a chip pad of the semiconductor chip and the substrate pad, and bonding the chip pad to the substrate pad using laser irradiated to the semiconductor chip.

A semiconductor device comprises a semiconductor die, comprising a stacking structure, a first bonding pad with a first bonding surface positioned away from the stacking structure, and a second bonding pad; a carrier comprising a connecting surface; a third bonding pad which comprises a second bonding surface and is arranged on the connecting surface, and a fourth bonding pad arranged on the connecting surface; and a conductive connecting layer comprising a first conducting part, comprising a first outer boundary, and formed between and directly contacting the first bonding pad and the third bonding pad; a second conducting part formed between the second bonding pad and the fourth bonding pad; and a blocking part covering the first conducting part.

A multi-layer wafer and method of manufacturing such wafer are provided. The method includes applying at least one stress compensating polymer layer to at least one of two heterogeneous wafers and low temperature bonding the two heterogeneous wafers to bond the stress compensating polymer layer to the other of the two heterogeneous wafers to form a multi-layer wafer pair. The multi-layer wafer comprises two heterogeneous wafers, at least one of the heterogeneous wafers having a stress compensating polymer layer. The two heterogeneous wafers are low temperature bonded together to bond the stress compensating polymer layer to the other of the two heterogeneous wafers.

A multi-layer wafer and method of manufacturing such wafer are provided. The method includes applying at least one stress compensating polymer layer to at least one of two heterogeneous wafers and low temperature bonding the two heterogeneous wafers to bond the stress compensating polymer layer to the other of the two heterogeneous wafers to form a multi-layer wafer pair. The multi-layer wafer comprises two heterogeneous wafers, at least one of the heterogeneous wafers having a stress compensating polymer layer. The two heterogeneous wafers are low temperature bonded together to bond the stress compensating polymer layer to the other of the two heterogeneous wafers.

Provided herein is a resin fluxed solder paste that exhibits a desirable solder bump reinforcement effect without requiring an underfill process. The disclosure also provides a mount structure. The resin fluxed solder paste includes a non-resinic powder containing a solder powder and an inorganic powder; and a flux containing a first epoxy resin, a curing agent, and an organic acid. The non-resinic powder accounts for 30 to 90 wt % of the total, and the surface of the inorganic powder is covered with an organic resin.