In an embodiment, a quantum device includes an interposer layer comprising a set of vias. In an embodiment, the quantum device includes a dielectric layer formed on a first side of the interposer, the dielectric layer including a set of transmission lines communicatively coupled to the set of vias. In an embodiment, the quantum device includes a plurality of qubit chips coupled to an opposite side of the interposer layer, each qubit chip of the plurality of qubit chips including: a plurality of qubits on a first side of the qubit chip and a plurality of protrusions on a second side of the qubit chip. In an embodiment, the quantum device includes a heat sink thermally coupled with the plurality of qubit chips, the heat sink comprising a plurality of recesses aligned with the plurality of protrusions of the plurality of qubit chips.

A semiconductor chip includes a single-crystal substrate and a metal electrode on the bottom surface of the substrate. The metal electrode has a region in which a first metal is exposed and a region in which a second metal is exposed, the second metal having a standard electrode potential different from that of the first metal.

In an embodiment, a quantum device includes an interposer layer comprising a set of vias. In an embodiment, the quantum device includes a dielectric layer formed on a first side of the interposer, the dielectric layer including a set of transmission lines communicatively coupled to the set of vias. In an embodiment, the quantum device includes a plurality of qubit chips coupled to an opposite side of the interposer layer, each qubit chip of the plurality of qubit chips including: a plurality of qubits on a first side of the qubit chip and a plurality of protrusions on a second side of the qubit chip. In an embodiment, the quantum device includes a heat sink thermally coupled with the plurality of qubit chips, the heat sink comprising a plurality of recesses aligned with the plurality of protrusions of the plurality of qubit chips.

A semiconductor device and method is disclosed. The semiconductor device may include a semiconductor substrate including an active area, a metal layer structure over the active area, wherein the metal layer structure is configured to form an electrical contact, the metal layer structure including a solder area, a buffer area, and a barrier area between the solder area and the buffer area, wherein, in the barrier area, the metal layer structure is further away from the active area than in the solder area and in the buffer area, and wherein each of the solder area and the buffer area is in direct contact with the active area or with a wiring layer structure arranged between the active area and the metal layer structure.

An object of the present invention is to improve manufacturing efficiency of a semiconductor device. The method of manufacturing a semiconductor device includes a sealing step of sealing a semiconductor chip mounted on the wiring substrate. The sealing step includes a step of arranging the wiring substrate between an upper mold and a lower mold, suctioning a lower surface of the wiring substrate with the plurality of suction holes, thereby holding the wiring substrate the upper mold, and a step of sealing the semiconductor chip, an upper surface of the wiring substrate, and the plurality of side surfaces of the wiring substrate such that each of the semiconductor chip, the upper surface of the wiring substrate, and the plurality of side surfaces of the wiring substrate is covered with the resin in the lower mold.

A semiconductor package includes a first package component include a first side, a second side opposite to the first side, and a plurality of recessed corners over the first side. The semiconductor package further includes a plurality of first stress buffer structures disposed at the recessed corners, and each of the first stress buffer structures has a curved surface. The semiconductor package further includes a second package component connected to the first package component and a plurality of connectors disposed between the first package component and the second package component. The connectors are electrically coupled the first package component and the second package component. The semiconductor package further includes an underfill material between the first package component and the second package component, and at least a portion of the curved surface of the first stress buffer structures is in contact with and embedded in the underfill material.

A die transfer method and a die transfer system thereof are disclosed. The die transfer method includes the following steps: providing a wafer to generate a plurality of dies; transferring a plurality of dies to a surface of a donor substrate to fix the plurality of dies on the surface of the donor substrate by a photoreactive adhesive layer; aligning the donor substrate with a target substrate, wherein the target substrate has a landing site and the position of at least one die corresponds to the position of the landing site; irradiating the donor substrate with a radiation beam to cause the photoreactive adhesive layer to drop the at least one die, such that the at least one die is transferred onto the landing site of the target substrate; and fixing the at least one die at the landing site.

A die transfer method and a die transfer system thereof are disclosed. The die transfer method includes the following steps: providing a wafer to generate a plurality of dies; transferring a plurality of dies to a surface of a substrate to fix the plurality of dies on the surface of the substrate; aligning the substrate with a target substrate, wherein the target substrate has a landing site and the position of at least one die corresponds to the position of the landing site; in an air environment or a liquid environment, executing lyophilic or lyophobic treatment as compared to the periphery respectively to a bonding surface between the at least one die and the landing site of the target substrate; transferring the at least one die onto the landing site of the target substrate; and fixing the at least one die at the landing site.

A semiconductor chip includes a single-crystal substrate and a metal electrode on the bottom surface of the substrate. The metal electrode has a region in which a first metal is exposed and a region in which a second metal is exposed, the second metal having a standard electrode potential different from that of the first metal.

The present disclosure is directed to a die having a metallized sidewall and methods of manufacturing the same. A contiguous metal layer is applied to each edge of a backside of a wafer. The wafer is cut at a base of a plurality of channels formed in the backside to create individual die each having a flange that is part of a sidewall of the die and includes a portion that is covered by the metal layer. When an individual die is coupled to a die pad, a semiconductive glue bonds the metal layer on the sidewall and a backside of the die to the die pad, which decreases the risk of delamination along the sides of the die. The flange also prevents the glue from contacting the active side of the die by acting as a barrier against adhesive creep of the glue up the sidewall of the die.