A metal base plate is rectangular in plan view, has a joining region set on a front surface, and has a center line, which is parallel to a pair of short sides that face each other, set in a middle interposed between the pair of short sides. A ceramic circuit board includes a ceramic board that is rectangular in plan view, a circuit pattern that is formed on a front surface of the ceramic board and has a semiconductor chip joined thereto, and a metal plate that is formed on a rear surface of the ceramic board and is joined to the joining region by solder. Here, the solder contains voids and is provided with a stress relieving region at one edge portion that is away from the center line. A density of voids included in the stress relieving region is higher than other regions of the solder.

A mounting apparatus for stacking and mounting two or more semiconductor chips at a plurality of locations on a substrate includes: a first mounting head for forming, at a plurality of locations on the substrate, temporarily stacked bodies in which two or more semiconductor chips are stacked in a temporarily press-attached state; and a second mounting head for forming chip stacked bodies by sequentially finally press-attaching the temporarily stacked bodies formed at the plurality of locations. The second mounting head includes: a press-attaching tool for heating and pressing an upper surface of a target temporarily stacked body to thereby finally press-attach the two or more semiconductor chips configuring the temporarily stacked body altogether; and one or more heat-dissipation tools having a heat-dissipating body which, by coming into contact with an upper surface of another stacked body positioned around the target temporarily stacked body, dissipates heat from the another stacked body.

An apparatus includes a product substrate having a transfer surface, and a semiconductor die defined, at least in part, by a first surface adjoined to a second surface that extends in a direction transverse to the first surface. The transfer surface includes ripples in a profile thereof such that an apex on an individual ripple is a point on a first plane and a trough on the individual ripple is a point on a second plane. The semiconductor die is disposed on the transfer surface between the first plane and the second plane such that the second surface of the semiconductor die extends transverse to the first plane and the second plane.

Interconnecting a first chip and a second chip by a bridge member includes a chip handler for handling the first chip and the second chip. Each of the first chip and the second chip has a first surface including a first set of terminals and a second surface opposite to the first surface. The chip handler has an opening and at least one support surface for supporting the first surfaces of the first chip and the second chip when the first chip and the second chip are mounted to the chip handler. A chip support member supports the first chip and the second chip from the second surfaces, and a bridge handler is provided for inserting the bridge member through the opening of the chip handler and for placing the bridge member onto the first sets of terminals of the first chip and the second chip.

A bonding apparatus includes a first holder, a second holder, a first interferometer, a housing, a gas supply and an airflow control cover. The first holder attracts and holds the first substrate. The second holder attracts and holds the second substrate. The first interferometer measures, by radiating light to the second holder or a first object which is moved along with the second holder in the first horizontal direction, a distance to the second holder or the first object in the first horizontal direction. The housing accommodates therein the first holder, the second holder and the first interferometer. The gas supply is provided at a lateral side of the housing, and supplies a gas into the housing. The airflow control cover is provided within the housing, and redirects a part of a flow of the gas supplied from the gas supply toward a first path of the light.

The present invention has: a heater; and a bonding tool having a lower surface on which a memory chip is adsorbed; and an upper surface attached to the heater, and is provided with a bonding tool which presses the peripheral edge of the memory chip to a solder ball in a first peripheral area of the lower surface and which presses the center of the memory chip (60) to a DAF having a heat resistance temperature lower than that of the solder ball in a first center area. The amount of heat transmitted from the first center area to the center of the memory chip is smaller than that transmitted from the first peripheral area (A) to the peripheral edge of the memory chip. Thus, the bonding apparatus in which the center of a bonding member can be heated to a temperature lower than that at the peripheral edge can be provided.

Embodiments of the present disclosure include method for sequentially mounting multiple semiconductor devices onto a substrate having a composite metal structure on both the semiconductor devices and the substrate for improved process tolerance and reduced device distances without thermal interference. The mounting process causes “selective” intermixing between the metal layers on the devices and the substrate and increases the melting point of the resulting alloy materials.

This mounting apparatus is provided with: a plurality of bonding stations each comprising a bonding apparatus for bonding a semiconductor chip onto a substrate wafer, and a chip supply apparatus for supplying the semiconductor chip to the bonding apparatus; and a single wafer transfer apparatus which transfers the substrate wafer in order to supply the substrate wafer to each of the plurality of bonding stations and to collect the substrate wafer from each of the plurality of bonding stations.

An industrial-scale system and method for handling precisely aligned and centered semiconductor substrate (e.g., wafer) pairs for substrate-to-substrate (e.g., wafer-to-wafer) aligning and bonding applications is provided. Some embodiments include an aligned substrate transport device having a frame member and a spacer assembly. The centered semiconductor substrate pairs may be positioned within a processing system using the aligned substrate transport device, optionally under robotic control. The centered semiconductor substrate pairs may be bonded together without the presence of the aligned substrate transport device in the bonding device. The bonding device may include a second spacer assembly which operates in concert with that of the aligned substrate transport device to perform a spacer hand-off between the substrates. A pin apparatus may be used to stake the substrates during the hand-off.

A bonding apparatus comprises a chip holding part that disposes a chip part onto a substrate that has been placed on a substrate stage. The bonding apparatus adjusts the inclination of a chip holding surface that releasably holds the chip part. The bonding apparatus comprises: an adjustment controller which stores inclination information pertaining to inclination respectively for locations on a stage main surface having the substrate placed thereon; and a conforming jig which has a conforming surface onto which the chip holding surface is pressed, and in which the inclination of the conforming surface can be changed such that the inclination of the chip holding surface corresponds to the inclination indicated by the inclination information.