A multi-chip package includes a field-programmable-gate-array (FPGA) integrated-circuit (IC) chip configured to perform a logic function based on a truth table, wherein the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip comprises multiple non-volatile memory cells therein configured to store multiple resulting values of the truth table, and a programmable logic block therein configured to select, in accordance with one of the combinations of its inputs, one from the resulting values into its output; and a memory chip coupling to the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip, wherein a data bit width between the field-programmable-gate-array (FPGA) integrated-circuit (IC) chip and the memory chip is greater than or equal to 64.

A light-emitting device includes a light-emitting element having a first-type semiconductor layer, a second-type semiconductor layer, an active stack between the first-type semiconductor layer and the second-type semiconductor layer, a bottom surface, and a top surface. A first electrode is disposed on the bottom surface and electrically connected to the first-type semiconductor layer. A second electrode is disposed on the bottom surface and electrically connected to the second-type semiconductor layer. A supporting structure is disposed on the top surface. The supporting structure has a thickness and a maximum width. A ratio of the maximum width to the thickness is of 2˜150.

A light-emitting device includes a light-emitting element having a first-type semiconductor layer, a second-type semiconductor layer, an active stack between the first-type semiconductor layer and the second-type semiconductor layer, a bottom surface, and a top surface. A first electrode is disposed on the bottom surface and electrically connected to the first-type semiconductor layer. A second electrode is disposed on the bottom surface and electrically connected to the second-type semiconductor layer. A supporting structure is disposed on the top surface. The supporting structure has a thickness and a maximum width. A ratio of the maximum width to the thickness is of 2˜150.

A memory array and single-crystal circuitry are provided by wafer bonding (e.g., adhesive wafer bonding or anodic wafer bonding) in the same integrated circuit and interconnected by conductors of a interconnect layer. Additional circuitry or memory arrays may be provided by additional wafer bonds and electrically connected by interconnect layers at the wafer bonding interface. The memory array may include storage or memory transistors having single-crystal epitaxial silicon channel material.

A memory array and single-crystal circuitry are provided by wafer bonding (e.g., adhesive wafer bonding or anodic wafer bonding) in the same integrated circuit and interconnected by conductors of a interconnect layer. Additional circuitry or memory arrays may be provided by additional wafer bonds and electrically connected by interconnect layers at the wafer bonding interface. The memory array may include storage or memory transistors having single-crystal epitaxial silicon channel material.

A method includes providing a structure including a carrier wafer, and a first device wafer with an adhesion layer between the carrier wafer and the first device wafer; and forming a plurality of first ablation structures in the structure, each of the plurality of first ablation structures extending through the first device wafer, the adhesion layer and a portion of the carrier wafer. Each of the plurality of first ablation structures has a portion inside the carrier wafer with a depth no greater than one half of a thickness of the carrier wafer. The first device wafer includes a plurality of first dies, each pair of adjacent first dies being separated by one of the plurality of first ablation structures. The plurality of first ablation structures are formed by either laser grooving or mechanical sawing.

A method includes providing a structure including a carrier wafer, and a first device wafer with an adhesion layer between the carrier wafer and the first device wafer; and forming a plurality of first ablation structures in the structure, each of the plurality of first ablation structures extending through the first device wafer, the adhesion layer and a portion of the carrier wafer. Each of the plurality of first ablation structures has a portion inside the carrier wafer with a depth no greater than one half of a thickness of the carrier wafer. The first device wafer includes a plurality of first dies, each pair of adjacent first dies being separated by one of the plurality of first ablation structures. The plurality of first ablation structures are formed by either laser grooving or mechanical sawing.

An electronic package including a middle patterned conductive layer, a first redistribution circuitry disposed on a first surface of the middle patterned conductive layer and a second redistribution circuitry disposed on a second surface of the middle patterned conductive layer is provided. The middle patterned conductive layer has a plurality of middle conductive pads. The first redistribution circuitry includes a first patterned conductive layer having a plurality of first conductive elements. Each of the first conductive elements has a first conductive pad and a first conductive via that form a T-shaped section. The second redistribution circuitry includes a second patterned conductive layer having a plurality of second conductive elements. Each of the second conductive elements has a second conductive pad and a second conductive via that form an inversed T-shaped section.

An electronic package including a middle patterned conductive layer, a first redistribution circuitry disposed on a first surface of the middle patterned conductive layer and a second redistribution circuitry disposed on a second surface of the middle patterned conductive layer is provided. The middle patterned conductive layer has a plurality of middle conductive pads. The first redistribution circuitry includes a first patterned conductive layer having a plurality of first conductive elements. Each of the first conductive elements has a first conductive pad and a first conductive via that form a T-shaped section. The second redistribution circuitry includes a second patterned conductive layer having a plurality of second conductive elements. Each of the second conductive elements has a second conductive pad and a second conductive via that form an inversed T-shaped section.

Hyperchip structures and methods of fabricating hyperchips are described. In an example, an integrated circuit assembly includes a first integrated circuit chip having a device side opposite a backside. The device side includes a plurality of transistor devices and a plurality of device side contact points. The backside includes a plurality of backside contacts. A second integrated circuit chip includes a device side having a plurality of device contact points thereon. The second integrated circuit chip is on the first integrated circuit chip in a device side to device side configuration. Ones of the plurality of device contact points of the second integrated circuit chip are coupled to ones of the plurality of device contact points of the first integrated circuit chip. The second integrated circuit chip is smaller than the first integrated circuit chip from a plan view perspective.