An integrated circuit device includes a semiconductor substrate; and a pad region over the semiconductor substrate. The integrated circuit device further includes an under-bump-metallurgy (UBM) layer over the pad region. The integrated circuit device further includes a conductive pillar on the UBM layer, wherein the conductive pillar has a sidewall surface and a top surface. The integrated circuit device further includes a protection structure over the sidewall surface of the conductive pillar, wherein sidewalls of the UBM layer are substantially free of the protection structure, and the protection structure is a non-metal material.

An integrated circuit device may include a multi-material toothed bond pad including (a) an array of vertically-extending teeth formed from a first material, e.g., aluminum, and (b) a fill material, e.g., silver, at least partially filling voids between the array of teeth. The teeth may be formed by depositing and etching aluminum or other suitable material, and the fill material may be deposited over the array of teeth and extending down into the voids between the teeth, and etched to expose top surfaces of the teeth. The array of teeth may collectively define an abrasive structure. The multi-material toothed bond pad may be bonded to another bond pad, e.g., using an ultrasonic or thermosonic bonding process, during which the abrasive teeth may abrade, break, or remove unwanted native oxide layers formed on the respective bond pad surfaces, to thereby create a direct and/or eutectic bonding between the bond pads.

An integrated circuit device may include a multi-material toothed bond pad including (a) an array of vertically-extending teeth formed from a first material, e.g., aluminum, and (b) a fill material, e.g., silver, at least partially filling voids between the array of teeth. The teeth may be formed by depositing and etching aluminum or other suitable material, and the fill material may be deposited over the array of teeth and extending down into the voids between the teeth, and etched to expose top surfaces of the teeth. The array of teeth may collectively define an abrasive structure. The multi-material toothed bond pad may be bonded to another bond pad, e.g., using an ultrasonic or thermosonic bonding process, during which the abrasive teeth may abrade, break, or remove unwanted native oxide layers formed on the respective bond pad surfaces, to thereby create a direct and/or eutectic bonding between the bond pads.

A device with pillar-shaped components, includes a substrate; a wiring layer disposed on the substrate; and pillar-shaped components disposed on any of the substrate and the wiring layer, each of the pillar-shaped components having a bottom part connected to the substrate and/or the wiring layer, a top part opposed to the bottom part, and a lateral face part extending from the bottom part and connected to the top part; wherein each of the pillar-shaped components includes a first pillar-shaped part formed by plating, a second pillar-shaped part formed on the first pillar-shaped part by plating, and a ring-like projection part formed on the lateral face part to project outward and extend in a circumferential direction, and to be in a position higher than a joint position between the first pillar-shaped part and the second pillar-shaped part.

A method of forming a conductive material on a semiconductor device. The method comprises removing at least a portion of a conductive pad within an aperture in a dielectric material over a substrate. The method further comprises forming a seed material at least within a bottom of the aperture and over the dielectric material, forming a protective material over the seed material within the aperture, and forming a conductive pillar in contact with the seed material through an opening in the protective material over surfaces of the seed material within the aperture. A method of forming an electrical connection between adjacent semiconductor devices, and a semiconductor device, are also described.

A method of forming a conductive material on a semiconductor device. The method comprises removing at least a portion of a conductive pad within an aperture in a dielectric material over a substrate. The method further comprises forming a seed material at least within a bottom of the aperture and over the dielectric material, forming a protective material over the seed material within the aperture, and forming a conductive pillar in contact with the seed material through an opening in the protective material over surfaces of the seed material within the aperture. A method of forming an electrical connection between adjacent semiconductor devices, and a semiconductor device, are also described.

Methods, techniques, and structures relating to die packaging. In one exemplary implementation, a die package interconnect structure includes a semiconductor substrate and a first conducting layer in contact with the semiconductor substrate. The first conducting layer may include a base layer metal. The base layer metal may include Cu. The exemplary implementation may also include a diffusion barrier in contact with the first conducting layer and a wetting layer on top of the diffusion barrier. A bump layer may reside on top of the wetting layer, in which the bump layer may include Sn, and Sn may be electroplated. The diffusion barrier may be electroless and may be adapted to prevent Cu and Sn from diffusing through the diffusion barrier. Furthermore, the diffusion barrier may be further adapted to suppress a whisker-type formation in the bump layer.

A method of manufacturing a multi-layer wafer is provided. Under bump metallization (UMB) pads are created on each of two heterogeneous wafers. A conductive means is applied above the UMB pads on at least one of the two heterogeneous wafers. The two heterogeneous wafers are low temperature bonded to adhere the UMB pads together via the conductive means. At least one stress compensating polymer layer may be applied to at least one of two heterogeneous wafers. The stress compensating polymer layer has a polymer composition of a molecular weight polymethylmethacrylate polymer at a level of 10-50% with added liquid multifunctional acrylates forming the remaining 50-90% of the polymer composition.

Provided is a method of manufacturing a structure that can be easily bonded to a bonding target. The method of manufacturing a structure includes: a conductive layer forming step of forming a conductive layer having conductivity on a part of a surface of an insulating support including at least one surface; a valve metal layer forming step of forming a valve metal layer that covers at least a part of the conductive layer; an anodic oxidation film forming step of forming an anodic oxidation film by performing an anodization treatment on the valve metal layer in a region on the conductive layer using the conductive layer as an electrode; a micropore forming step of forming a plurality of micropores that extend in a thickness direction on the anodic oxidation film; and a filling step of filling the micropores with a conductive material, in which a valve metal layer removing step of removing the valve metal layer having undergone the anodic oxidation film forming step is performed between the anodic oxidation film forming step and the filling step.

A method of manufacturing a semiconductor device having a conductive substrate having a first surface, a second surface opposite the first surface, and a passivation material covering a portion of the first surface can include applying a seed layer of conductive material to the first surface of the conductive substrate and to the passivation material, the seed layer having a first face opposite the conductive substrate. The method can include forming a plurality of pillars comprising layers of first and second materials. The method can include etching the seed layer to undercut the seed layer between the conductive substrate and the first material of at least one of the pillars. In some embodiments, a cross-sectional area of the seed layer in contact with the passivation material between the first material and the conductive substrate is less than the cross-sectional area of the second material.