A method of forming a chip assembly may include forming a plurality of cavities in a carrier; The method may further include arranging a die attach liquid in each of the cavities; arranging a plurality of chips on the die attach liquid, each chip comprising a rear side metallization and a rear side interconnect material disposed over the rear side metallization, wherein the rear side interconnect material faces the carrier; evaporating the die attach liquid; and after the evaporating the die attach liquid, fixing the plurality of chips to the carrier.

A bond chuck having individually-controllable regions, and associated systems and methods are disclosed herein. The bond chuck comprises a plurality of individual regions configured to be individually heated independent of one another. In some embodiments, the individual regions include a first region configured to be heated to a first temperature, and a second region peripheral to the first region and configured to be heated to a second temperature different than the first temperature. In some embodiments, the bond chuck further comprises (a) a first coil disposed within the first region and configured to heat the first region to the first temperature, and (b) a second coil disposed within the second region and configured to heat the second region to the second temperature. The bond chuck can be positioned proximate a substrate of a semiconductor device such that heating the first region and/or second region affect the viscosity of an adhesive used to bond substrates of the semiconductor device to one another. Accordingly, heating the first region and/or the second region can cause the adhesive on the substrate to flow in a lateral, predetermined direction.

A bond chuck having individually-controllable regions, and associated systems and methods are disclosed herein. The bond chuck comprises a plurality of individual regions that are movable relative to one another in a longitudinal direction. In some embodiments, the individual regions include a first region having a first outer surface, and a second region peripheral to the first region and including a second outer surface. The first region is movable in a longitudinal direction to a first position, and the second region is movable in the longitudinal direction to a second position, such that in the second position, the second outer surface of the second region extends longitudinally beyond the first outer surface of the first region. The bond chuck can be positioned proximate a substrate of a semiconductor device such that movement of the first region and/or second region affect a shape of the substrate, which thereby causes an adhesive on the substrate to flow in a lateral, predetermined direction.

A uniform pressure gang bonding device and fabrication method are presented using an expandable upper chamber with an elastic surface. Typically, the elastic surface is an elastomer material having a Young's modulus in a range of 40 to 1000 kilo-Pascal (kPA). After depositing a plurality of components overlying a substrate top surface, the substrate is positioned over the lower plate, with the top surface underlying and adjacent (in close proximity) to the elastic surface. The method creates a positive upper chamber medium pressure differential in the expandable upper chamber, causing the elastic surface to deform. For example, the positive upper chamber medium pressure differential may be in the range of 0.05 atmospheres (atm) and 10 atm. Typically, the elastic surface deforms between 0.5 millimeters (mm) and 20 mm, in response to the positive upper chamber medium pressure differential.

A system performs a direct transfer of a semiconductor device die from a first substrate to a second substrate. A semiconductor device die is disposed on a first side of the first substrate. The system includes a first conveyance mechanism to convey the first substrate, and a second conveyance mechanism to convey the second substrate with respect to the first substrate. The second conveyance mechanism includes a first portion and a second portion to clamp the second substrate adjacent to the first side of the first substrate. The first portion of the second conveyance mechanism has a concave shape and the second portion of the second conveyance mechanism has a convex counter shape corresponding to the concave shape of the first portion. The system also comprises a transfer mechanism disposed adjacent to the first conveyance mechanism to effectuate the direct transfer.

A power electronics method and assembly produced by the method. The assembly has a substrate, having a power semiconductor element, and an adhesion layer disposed therebetween, wherein the substrate has a first surface that faces a power semiconductor element, a power semiconductor element has a third surface that faces the substrate, the adhesion layer has a second surface which, preferably across the full area, contacts the third surface and has a first consistent surface contour having a first roughness, and wherein a fourth surface of the power semiconductor element that is opposite the third surface has a second surface contour having a second roughness, said second surface contour following the first surface contour.

A power electronics method and assembly produced by the method. The assembly has a substrate, having a power semiconductor element, and an adhesion layer disposed therebetween, wherein the substrate has a first surface that faces a power semiconductor element, a power semiconductor element has a third surface that faces the substrate, the adhesion layer has a second surface which, preferably across the full area, contacts the third surface and has a first consistent surface contour having a first roughness, and wherein a fourth surface of the power semiconductor element that is opposite the third surface has a second surface contour having a second roughness, said second surface contour following the first surface contour.

A substrate bonding apparatus includes a lower chuck, an upper chuck, an electric actuator on a central portion of the upper chuck, a pressure sensor, and a controller. The lower chuck may support a lower substrate, the upper chuck may face the lower chuck such that a lower surface of the upper chuck faces the upper surface of the lower chuck, and the upper chuck may support an upper substrate. The electric actuator may lower a bonding pin through the upper chuck to apply a pressure to the upper substrate supported on the upper chuck. The pressure sensor may be below the lower substrate supported on the lower chuck. The pressure sensor may sense a lowering pressure applied by the bonding pin to the pressure sensor in real time. The controller may control the lowering pressure applied by the bonding pin.

A semiconductor package includes a plurality of semiconductor chips on a substrate. The semiconductor chips include a first semiconductor chip, a second semiconductor chip, and a third semiconductor chip that are sequentially stacked on the substrate. The semiconductor package further includes a plurality of non-conductive layers between the substrate and the first semiconductor chip and between adjacent semiconductor chips among the semiconductor chips. The semiconductor chips include smaller widths as a distance from the substrate increases. Each of the non-conductive layers includes an extension protruding outward from a side surface of an overlying one of the semiconductor chips.

A transfer head, a transfer head array, and a method for transferring an inorganic light-emitting diode are provided. The transfer head for transferring an inorganic light-emitting diode includes a first groove and a second groove. The first groove and the second groove are arranged sequentially in a first direction, and are connected to each other. The first groove is configured to provide an inlet and an outlet for the inorganic light-emitting diode to enter and exit the transfer head. After the inorganic light-emitting diode enters the second groove through the first groove, at least a partial structure of the inorganic light-emitting diode is confined in the second groove. Picking up and transferring the inorganic light-emitting diode is realized by the transfer head with a simple structure.