A driving substrate, a micro LED transfer device and a micro LED transfer method are provided. A side surface of the driving substrate is arranged with a binding metal layer, a positioning layer is arranged around the binding metal layer, and a width of the positioning layer at a position away from the driving substrate is less than that a width at a position close to the driving substrate.

A semiconductor device includes: a semiconductor layer including a wire and an electrical element; and a plurality of metal pads on a surface of the semiconductor layer, wherein the plurality of metal pads includes a first metal pad and a second metal pad, wherein the second metal pad is smaller in surface area or diameter on the surface of the semiconductor layer than the first metal pad, and wherein the second metal pad is between a first region of the surface of the semiconductor layer where the first metal pad is and a second region of the surface of the semiconductor layer where a surface metal density is zero (0).

A wafer-level semiconductor die attachment method includes placing a semiconductor die of a plurality of semiconductor dies at an initial placement position to overlap a sub-mount pad on a sub-mount of a pre-singulated wafer. A die pad of the semiconductor die comes in contact with a solder layer deposited over the sub-mount pad. The semiconductor die and the sub-mount include a plurality of die and sub-mount mating features, respectively. The solder layer is heated locally to temporarily hold the semiconductor die at the initial placement position. The pre-singulated wafer is reflowed, when each semiconductor die is temporarily held at the corresponding initial placement position. During reflow, each semiconductor die slides from the initial placement position and a contact is established between the corresponding plurality of die and sub-mount mating features. Thereby, each semiconductor die is permanently attached to the corresponding sub-mount.

A pattern structure for a display device includes a substrate, a protrusion pattern on the substrate, a first conductive pattern covering an upper surface of the protrusion pattern, an interlayer insulating layer on the first conductive pattern and including a contact hole, and a second conductive pattern on the interlayer insulating layer and connected to the first conductive pattern. The contact hole overlaps the protrusion pattern and the first conductive pattern.

A semiconductor package includes: a first semiconductor chip including a plurality of front surface pads disposed on a first active surface of a first semiconductor substrate, at least one penetrating electrode penetrating at least a portion of the first semiconductor substrate and connected to the front surface pads, a first rear surface cover layer disposed on a first inactive surface of the first semiconductor substrate, a first rear surface dummy conductive layer penetrating a portion of the first rear surface cover layer; a second semiconductor chip including a second front surface cover layer disposed on a second active surface of a second semiconductor substrate, and a second front surface dummy conductive layer penetrating a portion of the second front surface cover layer; and at least one first bonded pad penetrating the first rear surface cover layer and the second front surface cover layer.

A method for forming a semiconductor device is provided. The method includes forming first bonding features and a first alignment mark including first patterns in a top die and forming second bonding features and a second alignment mark in a bottom wafer. The method also includes determining a first benchmark and a second benchmark. The method further includes aligning the top die with the bottom wafer using the first alignment mark and the second alignment mark. In a top view, at least two of the first patterns are oriented along a first direction, and at least two of the first patterns are oriented along a second direction that is different from the first direction. The top die is aligned with the bottom wafer by adjusting a virtual axis passing through the first benchmark and the second benchmark to be substantially parallel with the first direction.

A method for bonding a first substrate with a second substrate, characterized in that the first substrate and/or the second substrate is/are thinned before the bonding.

A semiconductor package includes: a first semiconductor chip including a plurality of front surface pads disposed on a first active surface of a first semiconductor substrate, at least one penetrating electrode penetrating at least a portion of the first semiconductor substrate and connected to the front surface pads, a first rear surface cover layer disposed on a first inactive surface of the first semiconductor substrate, a first rear surface dummy conductive layer penetrating a portion of the first rear surface cover layer; a second semiconductor chip including a second front surface cover layer disposed on a second active surface of a second semiconductor substrate, and a second front surface dummy conductive layer penetrating a portion of the second front surface cover layer; and at least one first bonded pad penetrating the first rear surface cover layer and the second front surface cover layer.

Integrated circuit structures and methods for a high precision die-to-wafer bonding technology for fabricating 3-D stacked IC dies. Embodiments include precise alignment structures and methods, and also provide fast fabrication techniques using simultaneous multi-die picking and placing of individual dies from a die-source wafer onto a recipient wafer. Stacked-die yields are improved over wafer-to-wafer bonding technologies by enabling testing and selection of known-good die-source dies before bonding onto the recipient wafer, and by providing optional physical alignment structures on the recipient wafer and/or die-source wafer. Embodiments enable, for example, fabrication of high-power, high-performance devices on ICs formed on GaAs or GaN die-source wafers and bonding individual die-source IC dies to ICs that include CMOS control and driver circuitry formed on an SOI recipient wafer. The resulting 3-D stacked IC dies may offer advantages that include scalability, reliability, and form-factor reduction.

A method for bonding a first substrate with a second substrate, characterized in that the first substrate and/or the second substrate is/are thinned before the bonding.