Packaging solutions for devices and systems comprising lateral GaN power transistors are disclosed, including components of a packaging assembly, a semiconductor device structure, and a method of fabrication thereof. In the packaging assembly, a GaN die, comprising one or more lateral GaN power transistors, is sandwiched between first and second leadframe layers, and interconnected using low inductance interconnections, without wirebonding. For thermal dissipation, the dual leadframe package assembly can be configured for either front-side or back-side cooling. Preferred embodiments facilitate alignment and registration of high current/low inductance interconnects for lateral GaN devices, in which contact areas or pads for source, drain and gate contacts are provided on the front-side of the GaN die. By eliminating wirebonding, and using low inductance interconnections with high electrical and thermal conductivity, PQFN technology can be adapted for packaging GaN die comprising one or more lateral GaN power transistors.

Provided are a device packing facility and method using DEHT and a device processing apparatus utilizing the DEHT. The device packaging facility includes a mounting unit providing bis(2-ethylhexyl) terephthalate (DEHT) between first and second devices to attach the first and second devices to each other, a processing unit thermally processing the first and second devices that are attached to each other to remove the DEHT and fix the first and second devices to each other, and a transfer unit transferring the first and second devices that are attached to each other from the mounting unit to the processing unit.

A method for manufacturing a semiconductor apparatus, including preparing a first substrate provided with a pad optionally having a plug and a second substrate or device provided with a plug, forming a solder ball on at least one of the pad or plug of first substrate and the plug of second substrate or device, covering at least one of a pad-forming surface of first substrate and a plug-forming surface of second substrate or device with a photosensitive insulating layer, forming an opening on the pad or plug of the substrate or device that has been covered with photosensitive insulating layer by lithography, pressure-bonding the second substrate or device's plug to the pad or plug of first substrate with the solder ball through the opening, electrically connecting pad or plug of first substrate to second substrate or device's plug by baking, and curing photosensitive insulating layer by baking.

According to the present invention, a semiconductor device includes a substrate including a first surface and a second surface opposite to the first surface, a first layer formed over the first surface, a second layer thicker than the first layer formed over the first portion of the first layer, the first and second layers being formed of a same material, a first semiconductor chip mounted over a second portion of the first layer; and a second semiconductor chip commonly mounted over the first semiconductor chip and the second layer.

Provided are a device packing facility and method using phthalate and a device processing apparatus utilizing the phthalate. The device packaging facility includes a mounting unit providing phthalate between first and second devices to attach the first and second devices to each other, a processing unit thermally processing the first and second devices that are attached to each other to remove the phthalate and fix the first and second devices to each other, and a transfer unit transferring the first and second devices that are attached to each other from the mounting unit to the processing unit.

Semiconductor device assemblies with solderless interconnects, and associated systems and methods are disclosed. In one embodiment, a semiconductor device assembly includes a first conductive pillar extending from a semiconductor die and a second conductive pillar extending from a substrate. The first conductive pillar may be connected to the second conductive pillar via an intermediary conductive structure formed between the first and second conductive pillars using an electroless plating solution injected therebetween. The first and second conductive pillars and the intermediary conductive structure may include copper as a common primary component, exclusive of an intermetallic compound (IMC) of a soldering process. A first sidewall surface of the first conductive pillar may be misaligned with respect to a corresponding second sidewall surface of the second conductive pillar. Such interconnects formed without IMC may improve electrical and metallurgical characteristics of the interconnects for the semiconductor device assemblies.

A semiconductor package includes a first substrate, a first flow channel and a second flow channel. The first flow channel is on the first substrate. The second flow channel is on the first substrate and in fluid communication with the first flow channel. The second flow channel is spaced from an inlet and an outlet of the first flow channel. The first flow channel and the second flow channel constitute a bonding region of the first substrate.

A system and method for reworking a flip chip includes use of a mill to remove an old flip chip, and a pick-and-place device for putting a new flip chip in place at the same location. The process may be automated, with the removal and the placement occurring sequentially without need for operator intervention. Other devices and processes may be part of the system/machine and process, for example cleaning following the milling, fluxing prior to the placement, and heating to cause solder reflow, to secure the new flip chip in place. Underfill may be employed to make for a more mechanically robust mounting of the new flip chip.

Electrical connection between electrodes provided respectively at facing positions in joint surfaces of substrates to be joined by chip lamination technology is conducted more securely. A method of manufacturing a semiconductor device includes: a first step of embedding electrodes in insulating layers exposed to the joint surfaces of a first substrate and a second substrate; a second step of subjecting the joint surfaces of the first substrate and the second substrate to chemical mechanical polishing, to form the electrodes into recesses recessed as compared to the insulating layers; a third step of laminating insulating films of a uniform thickness over the entire joint surfaces; a fourth step of forming an opening by etching in at least part of the insulating films covering the electrodes of the first substrate and the second substrate; a fifth step of causing the corresponding electrodes to face each other and joining the joint surfaces of the first substrate and the second substrate to each other; and a sixth step of heating the first substrate and the second substrate joined to each other, causing the electrode material to expand and project through the openings, and joining the corresponding electrodes to each other.

A method of manufacturing a semiconductor device includes embedding electrodes in insulating layers exposed to the joint surfaces of a first substrate and a second substrate, subjecting the joint surfaces of the first substrate and the second substrate to chemical mechanical polishing, to form the electrodes into recesses recessed as compared to the insulating layer, laminating insulating films of a uniform thickness over the entire joint surfaces, forming an opening by etching in at least part of the insulating films covering the electrodes of the first substrate and the second substrate, causing the corresponding electrodes to face each other and joining the joint surfaces of the first substrate and the second substrate to each other, heating the first substrate and the second substrate joined to each other, causing the electrode material to expand and project through the openings, and joining the corresponding electrodes to each other.