An electronic device is provided, including a substrate, a plurality of bonding pads, and a plurality of light emitting members, wherein the bonding pads are disposed on the substrate, and the light emitting members are disposed on the bonding pads. The light emitting members include a first pair of adjacent light-emitting members, a second pair of adjacent light-emitting members, and a third pair of adjacent light-emitting members. The first pair of adjacent light-emitting members, the second pair of adjacent light-emitting members, and the third pair of adjacent light-emitting members are arranged along the first direction in sequence. The first pair of adjacent light-emitting members has a first pitch, the second pair of adjacent light-emitting members has a second pitch, and the third pair of adjacent light-emitting members has a third pitch. The third pitch is greater than the second pitch, and the second pitch is greater than the first pitch.

Sintering device for sintering at least one electronic assembly, having a lower die and an upper die which is slidable towards the lower die, or a lower die which is slidable towards the upper die. The lower die forms a support for the assembly to be sintered and the upper die includes a receptacle for a pressure pad for exerting pressure directed towards the lower die, and a delimitation wall which laterally surrounds the pressure pad. The delimitation wall having an outer delimitation wall and an inner delimitation wall surrounded by the outer delimitation wall, the inner delimitation wall mounted so as to be slidable towards the outer delimitation wall and so as to be slid in the direction of the lower die such that, following the placing of the inner delimitation wall on the lower die, the pressure pad is displaceable in the direction of the lower die.

A bonding apparatus includes a chuck and a bonding head. The chuck is configured to carry a plurality of substrates to be bonded. The bonding head has a cavity facing the chuck and includes a divider, at least one pneumatic component and a diaphragm. The divider is disposed in the cavity and dividing the cavity into a plurality of compartments. The at least one pneumatic component is disposed in at least one of the compartments. The diaphragm covers the cavity and is disposed between the at least one pneumatic component and the chuck.

A die bonding tool includes a bond head that secures a semiconductor die against a planar surface of the bond head, an actuator system that moves the bond head and the semiconductor die towards a surface of a target substrate, and at least one contact sensor configured to detect an initial contact between a first region of the semiconductor die and the surface of the target substrate, where in response to detecting the initial contact between the semiconductor die and the target substrate, the actuator tilts the planar surface of the bond head and the semiconductor die to bring a second region of the semiconductor die into contact with the surface of the target substrate and thereby provide improved contact between the semiconductor die and the target substrate and more effective bonding including instances where the planar surface of the bond head and the target substrate surface are not parallel.

A bonding tool and a bonding method are provided. The method includes attaching a semiconductor die to a bonding tool having a first surface, wherein the bonding tool comprises a bending member movably arranged in a trench of the bonding tool, and the bending member protrudes from the first surface and bends the semiconductor die; moving the semiconductor die toward a semiconductor wafer to cause a retraction of the bending member and a partial bonding at a portion of the semiconductor die and the semiconductor wafer; and causing a full bonding between the semiconductor die and the semiconductor wafer subsequent to the partial bonding.

A bond tip for thermocompression bonding a bottom surface includes a die contact area and a low surface energy material covering at least a portion of the bottom surface. The low surface energy material may cover substantially all of the bottom surface, or only a peripheral portion surrounding the die contact area. The die contact area may be recessed with respect to the peripheral portion a depth at least as great as a thickness of a semiconductor die to be received in the recessed die contact area. A method of thermocompression bonding is also disclosed.

The present application provides methods, systems and devices for simultaneously bonding multiple semiconductor chips of different height profiles on a flexible substrate.

A bonding tool and a bonding method are provided. The method includes attaching a semiconductor die to a bonding tool having a first surface, wherein the bonding tool comprises a bending member movably arranged in a trench of the bonding tool, and the bending member protrudes from the first surface and bends the semiconductor die; moving the semiconductor die toward a semiconductor wafer to cause a retraction of the bending member and a partial bonding at a portion of the semiconductor die and the semiconductor wafer; and causing a full bonding between the semiconductor die and the semiconductor wafer subsequent to the partial bonding.

The present application provides methods, systems and devices for simultaneously bonding multiple semiconductor chips of different height profiles on a flexible substrate.

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.