A method of preparation of a first surface of an electronic component, the first surface being intended to be bonded to another electronic component by a direct bonding and the first surface having previously been submitted to a surface treatment in an atmosphere including nitrogen, for example, a treatment in a nitrogen plasma or an ozone UV treatment, the preparation method including: placing into contact the first surface with an aqueous solution including at least 90% water, for a contacting duration longer than or equal to 30 minutes; and then drying the first surface.

A die bonding apparatus includes: a mounting base including a mounting area on which a first member is mounted; a heater arranged below the mounting base; a side wall configured to surround the mounting area; a collet configured to hold a second member by vacuum-chucking at an end portion; a lid including a hole, the lid being mounted on the side wall; a moving structure configured to move the collet to transport the second member held by the collet through the hole for bonding the second member to the first member; and a gas-supplying tube arranged on the side wall and configured to supply a heating gas to a heating space formed by the side wall and the lid. The lid contains a material capable of: reflecting an infrared radiation caused by the heater and the heating gas; or absorbing and re-radiating the infrared radiation.

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.

A wafer-level pulling method includes securing a top holder to a plurality of chips; and securing a bottom holder to a wafer, wherein the plurality of chips are bonded to the wafer by a plurality of solder bumps. The wafer-level pulling method further includes softening the plurality of solder bumps; and stretching the plurality of softened solder bumps.

A chip-stacking apparatus for stacking a chip on a substrate is provided. The chip-stacking apparatus includes a substrate support configured to carry the substrate and a transport device configured to dispose a chip to the substrate. The transport device includes a bond head including a bond base and an attaching element disposed on the bond base and configured to allow the chip to be attached thereon. The center area of the attaching element is higher than an edge area of the attaching element relative to the bond base.

An apparatus for bonding a semiconductor chip to a package substrate, the apparatus comprising: a die-bonding unit configured to attach the semiconductor chip to the package substrate; a load-measuring unit installed at the die-bonding unit, the load-measuring unit including a panel having a plurality of regions and a plurality of load-measuring members with at least one load-measuring member arranged in each of the regions of the panel to measure load values applied to each of the regions; and a controller configured to determine a load and a flatness of the semiconductor chip based on the load values measured by the load-measuring members.

A manufacturing method includes the step of forming a diced semiconductor wafer (10) including semiconductor chips (11) from a semiconductor wafer (W) typically on a dicing tape (T1). The diced semiconductor wafer (10) on the dicing tape (T1) is laminated with a sinter-bonding sheet (20). The semiconductor chips (11) each with a sinter-bonding material layer (21) derived from the sinter-bonding sheet (20) are picked up typically from the dicing tape (T1). The semiconductor chips (11) each with the sinter-bonding material layer are temporarily secured through the sinter-bonding material layer (21) to a substrate. Through a heating process, sintered layers are formed from the sinter-bonding material layers (21) lying between the temporarily secured semiconductor chips (11) and the substrate, to bond the semiconductor chips (11) to the substrate. The semiconductor device manufacturing method is suitable for efficiently supplying a sinter-bonding material to individual semiconductor chips while reducing loss of the sinter-bonding material.

The present disclosure relates to an adhesive transfer film for bonding a semiconductor chip and a spacer to a substrate and a method for manufacturing a power module substrate by using same, the adhesive transfer film being obtained by manufacturing an Ag sintering paste in the form of a film. The present disclosure can reduce the process time by minimizing a sintering process, and can reduce equipment investment cost.

A mounting device includes a control device. The control device images an imaging range which includes an illuminant of a light emitting component and acquires a light emitting component image when mounting the light emitting component which includes the illuminant onto a board. Next, the control device detects coordinates (illuminant detected center coordinates) of a center of the illuminant based on the light emitting component image. The control device performs the mounting of the light emitting component such that the light emitting component is held, the light emitting component moves over the board, and a center of the illuminant is positioned at predetermined coordinates on the board based on the illuminant detected center coordinates, without using information relating to an outer shape of the light emitting component which is based on the light emitting component image.

In a system for aligning at least two semiconductor structures for coupling, an alignment device includes a mounting structure having at least first and second opposing portions. The alignment device also includes a first mounting portion movably coupled to the first portion of the mounting structure, the first mounting portion configured to couple to a first surface of a first semiconductor structure. The alignment device additionally includes a second mounting portion movably coupled to the second portion of the mounting structure, the second mounting portion configured to couple to a second surface of a second semiconductor structure. The alignment device further includes one or more imaging devices disposed above at least one of the first and second mounting portions of the alignment device, the imaging devices configured to capture and/or or detect alignment marks in at least the first semiconductor structure. A corresponding method for aligning two or more semiconductor structures for coupling is also provided.