A multi-layer pillar and method of fabricating the same is provided. The multi-layer pillar is used as an interconnect between a chip and substrate. The pillar has at least one low strength, high ductility deformation region configured to absorb force imposed during chip assembly and thermal excursions.

A method includes forming an under bump metallization (UBM) layer over a dielectric layer, forming a redistribution structure over the UBM layer, disposing a semiconductor device over the redistribution structure, removing a portion of the dielectric layer to form an opening to expose the UBM layer, and forming a conductive bump in the opening such that the conductive bump is coupled to the UBM layer.

A method includes forming an under bump metallization (UBM) layer over a dielectric layer, forming a redistribution structure over the UBM layer, disposing a semiconductor device over the redistribution structure, removing a portion of the dielectric layer to form an opening to expose the UBM layer, and forming a conductive bump in the opening such that the conductive bump is coupled to the UBM layer.

Implementations of a semiconductor package may include a pin coupled to a substrate. The pin may include a titanium sublayer, a nickel sublayer, and one of a silver and tin intermetallic layer or a copper and tin intermetallic layer, the one of the silver and tin intermetallic layer or the copper and tin intermetallic layer having a melting temperature greater than 260 degrees Celsius. The one of the silver and tin intermetallic layer or the copper and tin intermetallic layer may be formed by reflowing a tin layer and one of a silver layer or copper layer with a silver layer of the substrate where the substrate may be directly coupled to the one of the silver and tin intermetallic layer or the copper and tin intermetallic layer. The substrate may include a copper layer that was directly coupled with the silver layer before the reflow.

A semiconductor structure includes a semiconductor chip, a substrate and a plurality of bump segments. The bump segments include a first group of bump segments and a second group of bump segments collectively extended from an active surface of the semiconductor chip toward the substrate. Each bump segment of the second group of bump segments has a cross-sectional area greater than a cross-sectional area of each bump segment of the first group of bump segments. The first group of bump segments includes a first bump segment and a second bump segment. Each of the first bump segment and the second bump segment includes a tapered side surface exposed to an environment outside the bump segments. A portion of a bottom surface of the second bump segment is stacked on the first bump segment, and another portion of the bottom surface of the second bump segment is exposed to the environment.

Tools and systems for processing semiconductor devices, and methods of processing semiconductor devices are disclosed. In some embodiments, a method of using a tool for processing semiconductor devices includes a tool with a second material disposed over a first material, and a plurality of apertures disposed within the first material and the second material. The second material comprises a higher reflectivity than the first material. Each of the apertures is adapted to retain a package component over a support during an exposure to energy.

An electrically conductive pillar that can bond a base member and a member to be bonded together with high bonding strength with a bonding layer interposed therebetween and a method for manufacturing the same. Specifically, an electrically conductive pillar 1 is composed of a sintered body 12 of metal micro-particles disposed on a base member 11. The average particle size of the metal micro-particles is less than 1 μm as measured using a small-angle X-ray scattering method. An upper surface 12b of the sintered body 12 has a concave shape recessed on the base member 11 side. The metal micro-particles are preferably made of one or more metals selected from Ag and Cu.

In an embodiment, a method includes: stacking a plurality of first dies to form a device stack; revealing testing pads of a topmost die of the device stack; testing the device stack using the testing pads of the topmost die; and after testing the device stack, forming bonding pads in the topmost die, the bonding pads being different from the testing pads.

A copper pillar bump for an electrode pad of a semiconductor chip includes a first copper layer, a first metal layer formed directly on the first copper layer, a second copper layer formed directly on the first metal layer, and a second metal layer formed directly on the second copper layer, wherein the first metal layer and the second metal layer are made of a metal having a different etching rate than copper, wherein an outer perimeter ring of the first metal layer protrudes beyond a lateral surface of the first copper layer, and wherein an outer perimeter ring of the second metal layer protrudes beyond a lateral surface of the second copper layer.

A copper pillar bump for an electrode pad of a semiconductor chip includes a first copper layer, a first metal layer formed directly on the first copper layer, a second copper layer formed directly on the first metal layer, and a second metal layer formed directly on the second copper layer, wherein the first metal layer and the second metal layer are made of a metal having a different etching rate than copper, wherein an outer perimeter ring of the first metal layer protrudes beyond a lateral surface of the first copper layer, and wherein an outer perimeter ring of the second metal layer protrudes beyond a lateral surface of the second copper layer.