Embodiments disclose a package structure and a fabricating method. The package structure includes: a semiconductor chip; a first non-conductive layer covering a front surface of the semiconductor chip and part of a side wall of the semiconductor chip; a second non-conductive layer positioned on an upper surface of the first non-conductive layer and covering at least part of a side wall of the first non-conductive layer, wherein a melt viscosity of the first non-conductive layer is greater than a melt viscosity of the second non-conductive layer; a substrate; and a solder mask layer positioned on a surface of the substrate, where a first opening is provided in the solder mask layer. The semiconductor chip is flip-chip bonded on the substrate, a surface of the second non-conductive layer away from the first non-conductive layer and a surface of the solder mask layer away from the substrate are bonding surfaces.

A package structure is provided. The package structure includes a reinforced plate and multiple conductive structures penetrating through the reinforced plate. The package structure also includes a redistribution structure over the reinforced plate. The redistribution structure has multiple polymer-containing layers and multiple conductive features. The package structure further includes multiple chip structures bonded to the redistribution structure through multiple solder bumps. In addition, the package structure includes a protective layer surrounding the chip structures.

A semiconductor package according to the inventive concept includes a first semiconductor chip configured to include a first semiconductor device, a first semiconductor substrate, a plurality of through electrodes penetrating the first semiconductor substrate, and a plurality of first chip connection pads arranged on an upper surface of the first semiconductor substrate; a plurality of second semiconductor chips sequentially stacked on an upper surface of the first semiconductor chip and configured to each include a second semiconductor substrate, a second semiconductor device controlled by the first semiconductor chip, and a plurality of second chip connection pads arranged on an upper surface of the second semiconductor substrate; a plurality of bonding wires configured to connect the plurality of first chip connection pads to the plurality of second chip connection pads; and a plurality of external connection terminals arranged on a lower surface of the first semiconductor chip.

A semiconductor package including a substrate; a semiconductor stack on the substrate; an underfill between the substrate and the semiconductor stack; an insulating layer conformally covering surfaces of the semiconductor stack and the underfill; a chimney on the semiconductor stack; and a molding member surrounding side surfaces of the chimney, wherein the semiconductor stack has a first upper surface that is a first distance from the substrate and a second upper surface that is a second distance from the substrate, the first distance being greater than the second distance, wherein the chimney includes a thermally conductive filler on the first and second upper surfaces of the semiconductor stack, the thermally conductive filler having a flat upper surface; a thermally conductive spacer on the thermally conductive filler; and a protective layer on the thermally conductive spacer, and wherein an upper surface of the thermally conductive spacer is exposed.

A semiconductor device includes: a metal block; a semiconductor element fixed to an upper surface of the block with a first joining material; a main terminal fixed to an upper surface of the element with a second joining material; a signal terminal electrically connected to the element; and a mold resin covers the element, the first and second joining materials, a part of the block, of the main and signal terminals. In the element, a current flows in a longitudinal direction. A lower surface of the block is exposed from the resin. The main and the signal terminals are exposed from a side surface of the resin. The main terminal has a first portion in the resin, a second portion continuous with the first portion and bent downward outside the resin, and a third portion continuous with the second portion and substantially parallel to a lower surface of the resin.

A semiconductor device package and a method of forming the same are provided. The semiconductor device package includes a package substrate having a first surface and a second surface opposite to the first surface. Several integrated devices are bonded to the first surface of the package substrate. A first underfill element is disposed over the first surface and surrounds the integrated devices. A first molding layer is disposed over the first surface and surrounds the integrated devices and the first underfill element. A semiconductor die is bonded to the second surface of the package substrate. A second underfill element is disposed over the second surface and surrounds the semiconductor die. A second molding layer is disposed over the second surface and surrounds the semiconductor die and the second underfill element. Several conductive bumps are disposed over the second surface and adjacent to the second molding layer.

Structures and formation methods of a chip package structure are provided. The chip package structure includes a semiconductor die bonded over an interposer substrate. The chip package structure also includes a warpage release layer structure. The warpage release layer structure includes an organic material layer and an overlying high coefficient of thermal expansion (CTE) material layer with a CTE that is substantially equal to or greater than 9 ppm/° C. The organic material layer is in direct contact with the upper surface of the semiconductor die, and the overlying high CTE material layer covers the upper surface of the semiconductor die.

A semiconductor device includes a first switching element, a second switching element, an optical coupling element, a plurality of leads and an outer resin member. The first switching element includes a first semiconductor chip and a first inner resin member sealing the first semiconductor chip. The second switching element includes a second semiconductor chip and a second inner resin member sealing the second semiconductor chip. The optical coupling element includes a light-emitting element, a light-receiving element and a third inner resin member sealing the light-emitting element and the light-receiving element. The first and second switching element and the optical coupling element are provided with terminals projecting from the first to third inner resin member, and the plurality of leads are electrically connected to the terminals. The outer resin member seals the first and second switching elements, the optical coupling element, and the plurality of leads.

A method comprises the steps of providing a wafer; applying a redistribution layer, grinding a back side of the wafer; depositing a metal layer; and applying a singulation process. A semiconductor package comprises a metal-oxide-semiconductor field-effect transistor (MOSFET), a redistribution layer, and a metal layer. The MOSFET comprises a source electrode, a gate electrode, a drain electrode and a plurality of partial drain plugs. The source electrode, the gate electrode, and the drain electrode are positioned at a front side of the MOSFET.

A semiconductor device with high heat dissipation efficiency includes a base structure, a semiconductor chip, a heat dissipating structure, and a package body. The semiconductor chip is disposed on the base structure and has a first surface distant from the base structure. The heat dissipating structure includes a buffer layer and a first heat spreader. The buffer layer is disposed on the first surface of the semiconductor chip and a coverage rate thereof on the first surface is at least 10%. The first heat spreader is disposed on the buffer layer and bonded to the first surface of the semiconductor chip through the buffer layer. The package body encloses the semiconductor chip and the heat dissipating structure, and the package body and the buffer layer have the same heat curing temperature.