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 die bond head apparatus has a die bond head body coupled to a die bond head motion table, a die holder motion table mounted on the die bond head body and a die holder which is operative in use to secure a semiconductor die to a substrate. The die holder is positionable by the die holder motion table independently of the die bond head motion table.

A bond head assembly for a bonding machine is provided. The bond head assembly includes a body portion and a bonding tool for bonding a semiconductor element to a substrate. The bonding tool is secured to the body portion. The bond head assembly also includes at least one reflective optical element carried by the bond head assembly. The at least one reflective optical element is configured to be positioned along an optical path of the bonding machine such that a vision system of the bonding machine is configured to view a portion of the semiconductor element while being carried by the bonding tool prior to bonding of the semiconductor element to the substrate.

A semiconductor manufacturing apparatus that sequentially stacks a plurality of semiconductor chips while aligning the plurality of semiconductor chips on a stage. A condition determinator determines whether an apparatus performing a mounting processing stops during a mounting processing of the plurality of semiconductor chips. An evacuation controller evacuates, when it is determined that the apparatus performing the mounting processing stops, a group of semiconductor chips that has been stacked before the determination. A resuming determinator determines whether to resume the mounting processing after it is determined that the predetermined condition is satisfied. A return controller returns the evacuated group of semiconductor chips to a position before the evacuation and continues the mounting processing when it is determined that the mounting processing is resumed.

A stacked device includes a stacked structure in which a plurality of semiconductors are electrically connected to each other, the semiconductor includes a surface on which a plurality of terminals are provided, the plurality of terminals include a terminal that bonds and electrically connects the semiconductors to each other and a terminal that bonds the semiconductors to each other and does not electrically connect the semiconductors to each other, an area ratio of the plurality of terminals on the surface of the semiconductor is 40% or higher, and an area ratio of the terminals that bond and electrically connect the semiconductors to each other among the plurality of terminals is lower than 50%.

Semiconductor devices having measurement features and associated systems and methods are disclosed herein. In one embodiment, a semiconductor device includes a plurality of stacked semiconductor dies each having measurement features formed along an outer periphery of a surface thereof. One or more image capture devices can image the semiconductor device and a controller can detect the measurement features in imaging data received from the image capture devices. The controller can further determine the distance between two or more of the measurement features to estimate a bond line thickness between semiconductor dies in the stack.

In a method of aligning wafers, a second wafer having at least one second alignment key may be arranged over a first wafer having at least one first alignment key. At least one alignment hole may be formed by passing through the second wafer to expose the second alignment key and the first alignment key. The first wafer and the second wafer may be aligned with each other using the first alignment key and the second alignment key exposed through the alignment hole. Thus, the first alignment key and the second alignment key exposed through the alignment hole may be positioned at a same vertical line to accurately align the first wafer with the second wafer.

Die stacks and methods of making die stacks with very thin dies are disclosed. The die surfaces remain flat within a 5 micron tolerance despite the thinness of the die and the process steps of making the die stack. A residual flux height is kept below 50% of the spacing distance between adjacent surfaces or structures, e.g. in the inter-die spacing.

Die stacks and methods of making die stacks with very thin dies are disclosed. The die surfaces remain flat within a 5 micron tolerance despite the thinness of the die and the process steps of making the die stack. A residual flux height is kept below 50% of the spacing distance between adjacent surfaces or structures, e.g. in the inter-die spacing.

The disclosure is provided with: a temporary crimping step in which one or more semiconductor chips 10 are sequentially laminated while being temporarily crimped in each of two or more locations on a substrate 30 to thereby form chip stacks ST in a temporarily crimped state; and a permanent crimping step in which the top surfaces of all of the chip stacks ST formed in the temporarily crimped state are sequentially heated, pressurized, and permanently crimped. Furthermore, a specifying step is provided prior to the temporary crimping step for specifying a separation distance Dd which is the distance from the chip stacks ST under permanent crimping to a location at which the temperature of the substrate 30, the temperature having been raised by heating for the permanent crimping, becomes less than or equal to a prescribed permissible temperature Td, and in the temporary crimping step, the chip stacks ST in the temporarily crimped state are formed separated from each other by the separation distance Dd or more.