A method for transferring an electronic device includes steps as follows. A flexible carrier having a first surface on which the electronic device to be transferred is disposed and a second surface, a target substrate, a target substrate, and a light-transmissible pin having a pressing end are provided. The flexible carrier is spaced from the target substrate with the first surface thereof facing the target substrate. The flexible carrier is deformed by exerting the pin to press the second surface with the pressing end thereof at a position corresponding to the electronic device until the electronic device is in contact with the target substrate. An energy beam emitted from a light source standing outside the pin and then traveling through the pin and going out from the pressing end to bond the electronic device onto the target substrate is applied. The pin is released from pressing the flexible carrier.

An apparatus for bonding an electronic component including a first carrier, a second carrier, a driving mechanism, and a substrate adjustment mechanism is disclosed. The first carrier is configured to carry a first substrate and has a first carrying surface. The second carrier is configured to carry a second substrate and has a second carrying surface. The driving mechanism enables the first carrier and the second carrier to act in close proximity to each other and far away from each other. The substrate adjustment mechanism enables the first substrate and the second substrate disposed to be in a non-parallel configuration.

A semiconductor package is provided. The semiconductor package includes a first die having a plurality of first metal pads at a first bonding side and a second die over the first die, having a plurality of second metal pads at a second bonding side facing the first bonding side. Each of the first metal pads corresponds to each of the second metal pads with a pitch no greater than about 10 ?m. The semiconductor package further includes a first dielectric layer surrounding and in contact with a sidewall of the first metal pads and a second dielectric layer surrounding and in contact with a sidewall of the second metal pads. A method for manufacturing a semiconductor package is also provided.

A method of printing transferable components includes pressing a stamp including at least one transferable semiconductor component thereon on a target substrate such that the at least one transferable component and a surface of the target substrate contact opposite surfaces of a conductive eutectic layer. During pressing of the stamp on the target substrate, the at least one transferable component is exposed to electromagnetic radiation that is directed through the transfer stamp to reflow the eutectic layer. The stamp is then separated from the target substrate to delaminate the at least one transferable component from the stamp and print the at least one transferable component onto the surface of the target substrate. Related systems and methods are also discussed.

According to one embodiment, a method of manufacturing a semiconductor device includes: forming a laser peeling film above a first semiconductor substrate; forming, inside the laser peeling film, a thermal diffusion layer including a member has a coefficient of thermal conductivity higher than that of the laser peeling film is distributed in a plane parallel to a front surface of the first semiconductor substrate; forming a circuit layer including a semiconductor circuit above the laser peeling film; bonding the first and a second semiconductor substrates; applying a laser beam to a back surface of the first semiconductor substrate; and peeling the first semiconductor substrate to maintain the circuit layer on a side of the second semiconductor substrate.

A method for the transfer of components from a sender substrate to a receiver substrate includes provision and/or production of the components on the sender substrate, transfer of the components of the sender substrate to the transfer substrate, and transfer of the components from the transfer substrate to the receiver substrate. The components can be transferred selectively by means of bonding means and/or debonding means.

A bonding device is configured to bond a first element and a second element. The bonding device comprises an activating unit configured to activate a first bonding surface, which is a bonding surface of the first element, and a second bonding surface, which is a bonding surface of the second element, and a bonding unit configured to irradiate an active energy ray to cause the first bonding surface and the second bonding surface to come closer and bond with each other, from a state in which the first bonding surface and the second bonding surface face each other with a prescribed gap therebetween.

A method for transferring an electronic device includes steps as follows. A flexible carrier having a first surface on which the electronic device to be transferred is disposed and a second surface, a target substrate, a target substrate, and a light-transmissible pin having a pressing end are provided. The flexible carrier is spaced from the target substrate with the first surface thereof facing the target substrate. The flexible carrier is deformed by exerting the pin to press the second surface with the pressing end thereof at a position corresponding to the electronic device until the electronic device is in contact with the target substrate. An energy beam emitted from a light source standing outside the pin and then traveling through the pin and going out from the pressing end to bond the electronic device onto the target substrate is applied. The pin is released from pressing the flexible carrier.

A method of manufacturing a display device includes: immersing a mask including openings, in a solution; seating light-emitting diode chips respectively in the openings of the mask; arranging a first flexible substrate including first wirings thereon, below the mask, and aligning the first wirings to respectively correspond to the openings of the mask; removing from the solution, the first flexible substrate with the first wirings corresponding to the openings of the mask together with the mask with the light-emitting diode chips seated in the openings thereof; bonding the light-emitting diode chips and the first wirings to each other; providing a second flexible substrate including second wirings thereon, and aligning the second wirings to respectively correspond to the light-emitting diode chips; and bonding the light-emitting diode chips and the second wirings to each other, to form the display device.

A method of manufacturing a display device includes: immersing a mask including openings, in a solution; seating light-emitting diode chips respectively in the openings of the mask; arranging a first flexible substrate including first wirings thereon, below the mask, and aligning the first wirings to respectively correspond to the openings of the mask; removing from the solution, the first flexible substrate with the first wirings corresponding to the openings of the mask together with the mask with the light-emitting diode chips seated in the openings thereof; bonding the light-emitting diode chips and the first wirings to each other; providing a second flexible substrate including second wirings thereon, and aligning the second wirings to respectively correspond to the light-emitting diode chips; and bonding the light-emitting diode chips and the second wirings to each other, to form the display device.