An applying method includes the following steps. Firstly, a conductive adhesive including a plurality of conductive particles and an insulating binder is provided. Then, a carrier plate is provided. Then, a patterned adhesive is formed on the carrier plate by the conductive adhesive, wherein the patterned adhesive includes a first transferring portion. Then, a manufacturing device including a needle is provided. Then, the needle of the manufacturing device is moved to contact the first transferring portion. Then, the transferring portion is transferred to a board by the manufacturing device.

A bonding method of a first member includes arranging an activated front surface of a first member and an activated front surface of a second member so as to face each other with a back surface of the first member attached to a sheet, pushing a back surface of the first member through the sheet to closely attach the activated front surface of the first member and the activated front surface of the second member, and stripping the sheet from the back surface of the first member while maintaining a state in which the activated front surface of the first member is closely attached to the activated front surface of the second member.

A method and device for the alignment of substrates that are to be bonded. The method includes detecting and storing positions of alignment mark pairs located on surfaces of the substrates. and aligning the substrates with respect to each other in accordance with the detected positions.

Semiconductor packages with embedded bridge interconnects, and related assemblies and methods, are disclosed herein. In some embodiments, a semiconductor package may have a first side and a second side, and may include a bridge interconnect, embedded in a build-up material, having a first side with a plurality of conductive pads. The semiconductor package may also include a via having a first end that is narrower than a second end. The bridge interconnect and via may be arranged so that the first side of the semiconductor package is closer to the first side of the bridge interconnect than to the second side of the bridge interconnect, and so that the first side of the semiconductor package is closer to the first end of the via than to the second end of the via. Other embodiments may be disclosed and/or claimed.

Semiconductor packages with embedded bridge interconnects, and related assemblies and methods, are disclosed herein. In some embodiments, a semiconductor package may have a first side and a second side, and may include a bridge interconnect, embedded in a build-up material, having a first side with a plurality of conductive pads. The semiconductor package may also include a via having a first end that is narrower than a second end. The bridge interconnect and via may be arranged so that the first side of the semiconductor package is closer to the first side of the bridge interconnect than to the second side of the bridge interconnect, and so that the first side of the semiconductor package is closer to the first end of the via than to the second end of the via. Other embodiments may be disclosed and/or claimed.

An alignment mechanism comprises a rotary unit 61 with a first rotary axis 61c, three power transmission mechanisms 62, and three alignment action units 63. Each power transmission mechanism 62 comprises a first arm 621 and a second arm 622. The first arm 621 includes a first end 621a pivotably supported at a corresponding one of three different positions P11 to P13, and a second end 621b on the opposite side of the first end 621a. The second arm 622 includes a second rotary axis 622c and is pivotably supported on the second end 621b of the first arm 621 at a position different from the second rotary axis 622c. The alignment action units 63 are connected to corresponding second arms. The second rotary axes 622c are at three positions P21 to P23 separated from the rotary unit 61 toward three different directions centered on the first rotary axis 61c.

Semiconductor packages with embedded bridge interconnects, and related assemblies and methods, are disclosed herein. In some embodiments, a semiconductor package may have a first side and a second side, and may include a bridge interconnect, embedded in a build-up material, having a first side with a plurality of conductive pads. The semiconductor package may also include a via having a first end that is narrower than a second end. The bridge interconnect and via may be arranged so that the first side of the semiconductor package is closer to the first side of the bridge interconnect than to the second side of the bridge interconnect, and so that the first side of the semiconductor package is closer to the first end of the via than to the second end of the via. Other embodiments may be disclosed and/or claimed.

Semiconductor packages with embedded bridge interconnects, and related assemblies and methods, are disclosed herein. In some embodiments, a semiconductor package may have a first side and a second side, and may include a bridge interconnect, embedded in a build-up material, having a first side with a plurality of conductive pads. The semiconductor package may also include a via having a first end that is narrower than a second end. The bridge interconnect and via may be arranged so that the first side of the semiconductor package is closer to the first side of the bridge interconnect than to the second side of the bridge interconnect, and so that the first side of the semiconductor package is closer to the first end of the via than to the second end of the via. Other embodiments may be disclosed and/or claimed.

A method for constructing a ramp-stacked chip assembly starts by obtaining a set of semiconductor chips, including a first chip and a set of additional chips. Next, the method stacks the set of additional chips one at a time over the first chip, wherein each additional chip is horizontally offset from a preceding additional chip to form a ramp-stack. While stacking each additional chip, the method: applies an adhesive layer to a surface of a preceding chip in the ramp-stack; and uses a vacuum tool to pick up the additional chip and place the additional chip on the adhesive layer of the preceding chip. During this pick-and-place process, the vacuum tool spans most of a surface of the additional chip and also provides planar support for the additional chip, which causes a holding force of the vacuum tool to flatten the additional chip prior to placement on the preceding chip.

A bonding system includes a substrate transfer device configured to transfer a first substrate and a second substrate in a normal pressure atmosphere, a surface modifying apparatus configured to modify surfaces of the first substrate and the second substrate to be bonded with each other in a depressurized atmosphere, a load lock chamber in which the first substrate and the second substrate are delivered between the substrate transfer device and the surface modifying apparatus and in which an internal atmosphere of the load lock chamber is switchable between an atmospheric pressure atmosphere and the depressurized atmosphere, a surface hydrophilizing apparatus configured to hydrophilize the modified surfaces of the first substrate and the second substrate, and a bonding apparatus configured to bond the hydrophilized surfaces of the first substrate and the second substrate by an intermolecular force.