Embodiments of this application disclose a hybrid bonding structure and a hybrid bonding method. The hybrid bonding structure includes a first chip and a second chip. A surface of the first chip includes a first insulation dielectric and a first metal, and a first gap area exists between the first metal and the first insulation dielectric. A surface of the second chip includes a second insulation dielectric and a second metal. A surface of the first metal is higher than a surface of the first insulation dielectric. Metallic bonding is formed after the first metal is in contact with the second metal, and the first metal is longitudinally and transversely deformed in the first gap area. Insulation dielectric bonding is formed after the first insulation dielectric is in contact with the second insulation dielectric.

The present disclosure relates to a semiconductor device structure with a conductive polymer liner and a method for preparing the semiconductor device structure. The semiconductor device structure includes a first metal layer disposed over a semiconductor substrate, and a second metal layer disposed over the first metal layer. The semiconductor device structure also includes a conductive structure disposed between the first metal layer and the second metal layer. The conductive structure includes a first conductive via and a first conductive polymer liner surrounding the first conductive via.

A semiconductor device includes a semiconductor substrate, a dielectric structure, an electrical insulating and thermal conductive layer and a circuit layer. The electrical insulating and thermal conductive layer is disposed over the semiconductor substrate. The dielectric structure is disposed over the electrical insulating and thermal conductive layer, wherein a thermal conductivity of the electrical insulating and thermal conductive layer is substantially greater than a thermal conductivity of the dielectric structure. The circuit layer is disposed in the dielectric structure.

A semiconductor device includes a semiconductor substrate, a dielectric structure, an electrical insulating and thermal conductive layer and a circuit layer. The electrical insulating and thermal conductive layer is disposed over the semiconductor substrate. The dielectric structure is disposed over the electrical insulating and thermal conductive layer, wherein a thermal conductivity of the electrical insulating and thermal conductive layer is substantially greater than a thermal conductivity of the dielectric structure. The circuit layer is disposed in the dielectric structure.

A micro LED display manufacturing method according to various embodiments may include: a first operation of bonding an anisotropic conductive film including a plurality of conductive particles onto one surface of a prepared substrate, the one surface including a circuit part; a second operation of forming a bonding layer on the anisotropic conductive film; a third operation of positioning a plurality of micro LED chips above the bonding layer, the micro LED chips being arranged on a carrier substrate while being spaced a first distance apart from the substrate; a fourth operation of attaching the plurality of micro LED chips onto the bonding layer by means of laser transfer; and a fifth operation of forming a conductive structure for electrically connecting a connection pad to the circuit part through the conductive particles by means of heating and pressurizing.

At least one polymer material may be employed to facilitate bonding between the semiconductor dies. Plasma treatment, formation of a blended polymer, or formation of polymer hairs may be employed to enhance bonding. Alternatively, air gaps can be formed by subsequently removing the polymer material to reduce capacitive coupling between adjacent bonding pads.

At least one polymer material may be employed to facilitate bonding between the semiconductor dies. Plasma treatment, formation of a blended polymer, or formation of polymer hairs may be employed to enhance bonding. Alternatively, air gaps can be formed by subsequently removing the polymer material to reduce capacitive coupling between adjacent bonding pads.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes an active interposer including a programmable unit, a first memory die positioned above the active interposer and including a storage unit, and a first logic die positioned below the active interposer. The active interposer, the first memory die, and the first logic die are electrically coupled.

The present application discloses a method for fabricating a semiconductor device. The method includes providing a substrate, forming a first pad above the substrate, forming a first redistribution conductive layer on the first pad, and forming a first redistribution thermal release layer on the first redistribution conductive layer. The first redistribution conductive layer and the first redistribution thermal release layer together form a first redistribution structure and the first redistribution thermal release layer is configured to sustain a thermal resistance between about 0.04° C. cm.sup.2/Watt and about 0.25° C. cm.sup.2/Watt.

The present application discloses a method for fabricating a semiconductor device. The method includes providing a substrate, forming a first pad above the substrate, forming a first redistribution conductive layer on the first pad, and forming a first redistribution thermal release layer on the first redistribution conductive layer. The first redistribution conductive layer and the first redistribution thermal release layer together form a first redistribution structure and the first redistribution thermal release layer is configured to sustain a thermal resistance between about 0.04° C. cm.sup.2/Watt and about 0.25° C. cm.sup.2/Watt.