A method for bonding two superconducting integrated circuits (“chips”), such that the bonds electrically interconnect the chips. A plurality of indium-coated metallic posts may be deposited on each chip. The indium bumps are aligned and compressed with moderate pressure at a temperature at which the indium is deformable but not molten, forming fully superconducting connections between the two chips when the indium is cooled down to the superconducting state. An anti-diffusion layer may be applied below the indium bumps to block reaction with underlying layers. The method is scalable to a large number of small contacts on the wafer scale, and may be used to manufacture a multi-chip module comprising a plurality of chips on a common carrier. Superconducting classical and quantum computers and superconducting sensor arrays may be packaged.

A method of using an optoelectronic semiconductor stamp to manufacture an optoelectronic semiconductor device comprises the following steps: a preparation step: preparing at least one optoelectronic semiconductor stamp group and a target substrate, wherein each optoelectronic semiconductor stamp group comprises at least one optoelectronic semiconductor stamp, each optoelectronic semiconductor stamp comprises a plurality of optoelectronic semiconductor components disposed on a heat conductive substrate, each optoelectronic semiconductor component has at least one electrode, and the target substrate has a plurality of conductive portions; an align-press step: aligning and attaching at least one optoelectronic semiconductor stamp to the target substrate, so that the electrodes are pressed on the corresponding conductive portions; and a bonding step: electrically connecting the electrodes to the corresponding conductive portions.

A quantum computing system can include a first substrate including one or more quantum control devices. The quantum computing system can include a second substrate including one or more quantum circuit elements. The quantum computing system can include one or more tin contact bonds formed on the first substrate and the second substrate. The tin contact bonds can bond the first substrate to the second substrate. The tin contact bonds can be or can include tin, such as a tin alloy.

A semiconductor package includes a redistribution structure, a first conductive pillar and a second conductive pillar, and a semiconductor device. The redistribution structure has a first surface and a second surface opposite to the first surface. The first conductive pillar and the second conductive pillar are disposed on the first surface of the redistribution structure and electrically connected with the redistribution structure, wherein a maximum lateral dimension of the first conductive pillar is greater than a maximum lateral dimension of the second conductive pillar, and a topography variation of a top surface of the first conductive pillar is greater than a topography variation of a top surface of the second conductive pillar. The semiconductor device is disposed over the first surface of the redistribution structure, wherein the semiconductor device comprises a third conductive pillar and a fourth conductive pillar, the third conductive pillar is bonded to first conductive pillar through a first joint structure, and the fourth conductive pillar is bonded to second conductive pillar through a second joint structure.

An integrated circuit device having separate dies for programmable logic fabric and circuitry to operate the programmable logic fabric are provided. A first integrated circuit die may include field programmable gate array fabric. A second integrated circuit die may be coupled to the first integrated circuit die. The second integrated circuit die may include fabric support circuitry that operates the field programmable gate array fabric of the first integrated circuit die.

A quantum computing system can include a first substrate including one or more quantum control devices. The quantum computing system can include a second substrate including one or more quantum circuit elements. The quantum computing system can include one or more tin contact bonds formed on the first substrate and the second substrate. The tin contact bonds can bond the first substrate to the second substrate. The tin contact bonds can be or can include tin, such as a tin alloy.

Contact bumps between a contact pad and a substrate can include a rough surface that can mate with the material of the substrate of which may be flexible. The rough surface can enhance the bonding strength of the contacts, for example, against shear and tension forces, especially for flexible systems such as smart label and may be formed via roller or other methods.

Contact bumps between a contact pad and a substrate can include a rough surface that can mate with the material of the substrate of which may be flexible. The rough surface can enhance the bonding strength of the contacts, for example, against shear and tension forces, especially for flexible systems such as smart label and may be formed via roller or other methods.

Provided is a method for transferring and bonding devices. The method includes applying an adhesive layer to a carrier, arranging a plurality of devices, attaching the arranged devices to the carrier, applying a polymer film to a substrate, aligning the carrier to which the plurality of devices are attached with the substrate, bonding the plurality of devices to the substrate by radiating laser, and releasing the carrier from the substrate to which the plurality of devices are bonded.

A method for bonding a first substrate and a second substrate, the first substrate having at least one first connection extending from one side of the first substrate, the method comprising fabricating a first adhesive material around and along a height of the at least one first connection; and bonding the at least one first connection, the first adhesive material, and the second substrate.