The present invention relates to a semiconductor structure and a manufacturing method thereof. The semiconductor structure includes: a first substrate; a first adhesive layer disposed on a surface of the first substrate; and a first bonding layer disposed on a surface of the first adhesive layer. A density of the first adhesive layer is greater than a density of the first bonding layer. The first adhesive layer of the semiconductor structure has higher adhesion with the first substrate and first bonding layer, such that it is advantageous to improve a performance of the semiconductor structure.

Semiconductor devices, methods of manufacture thereof, and packaged semiconductor devices are disclosed. In one embodiment, a method of manufacturing a semiconductor device includes forming a plurality of contact pads over a substrate, and forming an insulating material over the plurality of contact pads and the substrate. The insulating material is patterned to form an opening over each of the plurality of contact pads, and the plurality of contact pads is cleaned. The method includes forming an under-ball metallization (UBM) structure over the plurality of contact pads and portions of the insulating material. Cleaning the plurality of contact pads recesses a top surface of each of the plurality of contact pads.

Semiconductor devices, methods of manufacture thereof, and packaged semiconductor devices are disclosed. In one embodiment, a method of manufacturing a semiconductor device includes forming a plurality of contact pads over a substrate, and forming an insulating material over the plurality of contact pads and the substrate. The insulating material is patterned to form an opening over each of the plurality of contact pads, and the plurality of contact pads is cleaned. The method includes forming an under-ball metallization (UBM) structure over the plurality of contact pads and portions of the insulating material. Cleaning the plurality of contact pads recesses a top surface of each of the plurality of contact pads.

The present invention provides a Cu alloy bonding wire for a semiconductor device, where the bonding wire can satisfy requirements of high-density LSI applications. In the Cu alloy bonding wire for a semiconductor device, the abundance ratio of a crystal orientation <110> having an angular difference of 15 degrees or less from a direction perpendicular to one plane including a wire center axis to crystal orientations on a wire surface is 25% or more and 70% or less in average area percentage.

The present invention provides a Cu alloy bonding wire for a semiconductor device, where the bonding wire can satisfy requirements of high-density LSI applications. In the Cu alloy bonding wire for a semiconductor device, the abundance ratio of a crystal orientation <110> having an angular difference of 15 degrees or less from a direction perpendicular to one plane including a wire center axis to crystal orientations on a wire surface is 25% or more and 70% or less in average area percentage.

A bonding wire for a semiconductor device, characterized in that the bonding wire includes a Cu alloy core material and a Pd coating layer formed on a surface of the Cu alloy core material, the bonding wire contains an element that provides bonding reliability in a high-temperature environment, and a strength ratio defined by the following Equation (1) is 1.1 to 1.6:
Strength ratio=ultimate strength/0.2% offset yield strength.(1)

A bonding wire for a semiconductor device, characterized in that the bonding wire includes a Cu alloy core material and a Pd coating layer formed on a surface of the Cu alloy core material, the bonding wire contains an element that provides bonding reliability in a high-temperature environment, and a strength ratio defined by the following Equation (1) is 1.1 to 1.6:
Strength ratio=ultimate strength/0.2% offset yield strength.(1)

A resistive element includes: a semiconductor substrate; a first insulating film deposited on the semiconductor substrate; a resistive layer deposited on the first insulating film; a second insulating film deposited to cover the first insulating film and the resistive layer; a first electrode deposited on the second insulating film and electrically connected to the resistive layer; a relay wire deposited on the second insulating film without being in contact with the first electrode, and including a resistive-layer connection terminal electrically connected to the resistive layer and a substrate connection terminal connected to the semiconductor substrate with an ohmic contact; and a second electrode deposited on a bottom side of the semiconductor substrate, wherein a resistor is provided between the first electrode and the second electrode.

A resistive element includes: a semiconductor substrate; a first insulating film deposited on the semiconductor substrate; a resistive layer deposited on the first insulating film; a second insulating film deposited to cover the first insulating film and the resistive layer; a first electrode deposited on the second insulating film and electrically connected to the resistive layer; a relay wire deposited on the second insulating film without being in contact with the first electrode, and including a resistive-layer connection terminal electrically connected to the resistive layer and a substrate connection terminal connected to the semiconductor substrate with an ohmic contact; and a second electrode deposited on a bottom side of the semiconductor substrate, wherein a resistor is provided between the first electrode and the second electrode.

Dies and/or wafers including conductive features at the bonding surfaces are stacked and direct hybrid bonded at a reduced temperature. The surface mobility and diffusion rates of the materials of the conductive features are manipulated by adjusting one or more of the metallographic texture or orientation at the surface of the conductive features and the concentration of impurities within the materials.