Tools and systems for processing semiconductor devices, and methods of processing semiconductor devices are disclosed. In some embodiments, a method of using a tool for processing semiconductor devices includes a tool with a second material disposed over a first material, and a plurality of apertures disposed within the first material and the second material. The second material comprises a higher reflectivity than the first material. Each of the apertures is adapted to retain a package component over a support during an exposure to energy.

A bonding apparatus includes a first holder configured to hold a first substrate divided into multiple chips with a tape and a ring frame therebetween, the first substrate being attached to the tape, and an edge of the tape being attached to the ring frame; a second holder configured to hold a second substrate, which is disposed on an opposite side to the tape with respect to the first substrate therebetween, while maintaining a distance from the first substrate; and a pressing device configured to press the multiple chips one by one with the tape therebetween to press and bond the corresponding chip to the second substrate.

A method of manufacturing a semiconductor memory device includes processing a first substrate including a first align mark and a first structure, processing a second substrate including a second align mark and a second structure, orientating the first substrate and the second substrate such that the first structure and the second structure face each other, and controlling alignment between the first structure and the second structure by using the first align mark and the second align mark to couple the first structure with the second structure.

A method of manufacturing a semiconductor memory device includes processing a first substrate including a first align mark and a first structure, processing a second substrate including a second align mark and a second structure, orientating the first substrate and the second substrate such that the first structure and the second structure face each other, and controlling alignment between the first structure and the second structure by using the first align mark and the second align mark to couple the first structure with the second structure.

An integrated circuit package substrate (ICPS) system includes a die including a first array of connectors and a substrate including a second array of connectors that is configured to be thermocompression bonded to the first array of connectors at a bonding temperature that is above a solder melting temperature. The first die is bonded to the substrate such that the first die is asymmetric with respect to a substrate center, and the second array of connectors is adjusted, at an alignment temperature that is below the solder melting temperature, for thermal expansion to the bonding temperature with respect to a reference point that is not a first die center.

This chip mounting system simultaneously images an alignment mark disposed on a substrate (WT) and an alignment mark disposed on a chip (CP), with the alignment marks disposed on the substrate (WT) and the chip (CP) being separated by a first distance at which the alignment marks fall within a depth-of-field range of imaging devices (35a, 35b). The chip mounting system calculates a relative positional deviation amount between the substrate (WT) and the chip (CP) from the imaged images of the alignment marks imaged by the imaging devices (35a, 35b) and, based on the calculated positional deviation amount, relatively moves the chip (CP) with respect to the substrate (WT) in a direction in which the positional deviation amount therebetween decreases.

A semiconductor manufacturing method of mounting a semiconductor chip or a stacked body of semiconductor chips on a support substrate placed on a stage, determines whether a predetermined condition is satisfied during a mounting processing of the semiconductor chip or the stacked body, evacuates, together with the support substrate, the semiconductor chip or the stacked body that has mounted on the support substrate before the determination when it is determined that the predetermined condition is satisfied, determines whether to resume the mounting processing of the semiconductor chip or the stacked body after the evacuation; and returns the evacuated semiconductor chip or the evacuated stacked body to a position before the evacuation and continuing the mounting processing when it is determined that the mounting processing is resumed.

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.

An alignment mark at a position that overlaps an area in which an anisotropic conductive film is pasted, and to accurately perform alignment using an image captured by a camera. An alignment method in which an electronic component is mounted on the obverse surface of a transparent substrate with a conductive adhesive agent interposed therebetween, a substrate-side alignment mark and a component-side alignment mark are adjusted from the captured image, and the position at which the electronic component is mounted on the transparent substrate is aligned, wherein in the conductive adhesive agent, conductive particles are in a regular arrangement as viewed from a planar perspective, and in the captured image, the outside edges of the alignment marks exposed between the conductive particles are intermittently visible as line segments (S) along the imaginary line segments of the outside edges of the alignment mark.

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.