A chip structure includes a first substrate, a second substrate, a conductive via, and a redistribution layer. The first substrate has a first inclined sidewall. The second substrate is located on a bottom surface of the first substrate, and has an upper portion and a lower portion. The lower portion extends from the upper portion. The upper portion is between the first substrate and the lower portion. The upper portion has a second inclined sidewall, and a slope of the first inclined sidewall is substantially equal to a slope of the second inclined sidewall. The conductive via is in the lower portion. The redistribution layer extends from a top surface of the first substrate to a top surface of the lower portion of the second substrate sequentially along the first inclined sidewall and the second inclined sidewall, and is electrically connected to the conductive via.

A micro-LED display panel including a substrate, an anisotropic conductive film, and a plurality of micro-LEDs is provided. The anisotropic conductive film is disposed on the substrate. The micro-LEDs and the anisotropic conductive film are disposed at the same side of the substrate, and the micro-LEDs are electrically connected to the substrate through the anisotropic conductive film. Each of the micro-LEDs includes an epitaxial layer and an electrode layer electrically connected to the epitaxial layer, and the electrode layers comprises a first electrode and a second electrode which are located between the substrate and the corresponding epitaxial layer. A ratio of a thickness of each of the electrode layers to a thickness of the corresponding epitaxial layer ranges from 0.1 to 0.5, and a gap between the first electrode and the second electrode of each of the micro-LEDs is in a range of 1 μm to 30 μm.

A transmitter component includes an input terminal and a first semiconductor portion with doped regions of a control-side interface circuit. The control-side interface circuit converts a digital input signal received at the input terminal into a transmit radio frequency signal. A control-side metallization structure on at least one of two horizontal main surfaces of the first semiconductor portion includes at least a portion of a control-side antenna structure that emits the transmit radio frequency signal as radio wave. A transceiver circuit may include the transmitter component and a receiver component.

A semiconductor package structure, an electronic device, and method for manufacturing the same are provided. The semiconductor package structure includes a wiring structure, a first electronic device, a second electronic device, and a protection material. The first electronic device is disposed on the wiring structure. The second electronic device is disposed on the wiring structure. The second electronic device defines a plurality of recesses on a first lateral side surface thereof. The protection material is disposed on the wiring structure and encapsulates the recesses of the second electronic device.

Direct bonded stack structures for increased reliability and improved yields in microelectronics are provided. Structural features and stack configurations are provided for memory modules and 3DICs to reduce defects in vertically stacked dies. Example processes alleviate warpage stresses between a thicker top die and direct bonded dies beneath it, for example. An etched surface on the top die may relieve warpage stresses. An example stack may include a compliant layer between dies. Another stack configuration replaces the top die with a layer of molding material to circumvent warpage stresses. An array of cavities on a bonding surface can alleviate stress forces. One or more stress balancing layers may also be created on a side of the top die or between other dies to alleviate or counter warpage. Rounding of edges can prevent stresses and pressure forces from being destructively transmitted through die and substrate layers. These measures may be applied together or in combinations in a single package.

A chip structure includes a first substrate, a second substrate, a conductive via, and a redistribution layer. The first substrate has a first inclined sidewall. The second substrate is located on a bottom surface of the first substrate, and has an upper portion and a lower portion. The lower portion extends from the upper portion. The upper portion is between the first substrate and the lower portion. The upper portion has a second inclined sidewall, and a slope of the first inclined sidewall is substantially equal to a slope of the second inclined sidewall. The conductive via is in the lower portion. The redistribution layer extends from a top surface of the first substrate to a top surface of the lower portion of the second substrate sequentially along the first inclined sidewall and the second inclined sidewall, and is electrically connected to the conductive via.

A stack package is disclosed. A first semiconductor die and a supporter are disposed on a package substrate. The supporter may include a second side facing a first side of the first semiconductor die having a substantially inclined surface. A second semiconductor die is stacked on the first semiconductor die and on the supporter. An encapsulant layer is formed to fill a portion between the supporter and the first semiconductor die.

A method of manufacture for a semiconductor package includes; forming a molding member on side surfaces of the semiconductor chips, using an adhesive to attach a carrier substrate to upper surfaces of the molding member and the semiconductor chips, using a first blade having a first blade-width to cut away selected portions of the carrier substrate and portions of the adhesive underlying the selected portions of the carrier substrate, and using the first blade to partially cut into an upper surface of the molding member to form a first cutting groove, wherein the selected portions of the carrier substrate are dispose above portions of the molding member between adjacent ones of semiconductor chips, using a second blade having a second blade-width narrower than the first blade-width to cut through a lower surface of the molding member to form a second cutting groove, wherein a combination of the first cutting groove and the second cutting groove separate a package structure including a semiconductor chip supported by a cut portion of the carrier substrate and bonding the package structure to an upper surface of a package substrate.

A semiconductor device assembly can include a substrate including a plurality of external connections. The assembly can include a first individual module and a first bond pad. The first individual module can be disposed on the substrate such that the first side of the first individual module faces the substrate. In some embodiments, the first individual module electrically is coupled to an external connection of the substrate via the first bond pad. The assembly can include a second individual module comprising a plurality of lateral sides. The second individual module can be disposed over the first individual module. In some embodiments, a first lateral side of the second individual module includes a first step forming a first overhang portion and a first recess. In some embodiments, the first bond pad is vertically aligned with the first recess of the second individual module.

Disclosed herein are structures and techniques related to singulation of microelectronic components with direct bonding interfaces. For example, in some embodiments, a microelectronic component may include: a surface, wherein conductive contacts are at the surface; a trench at a perimeter of the surface; and a burr in the trench.