A method of forming surface protrusions on an article, and the article with the protrusions attached. The article may be an Integrated Circuit (IC) chip, a test probe for the IC chip or any suitable substrate or nanostructure. The surface protrusions are electroplated to a template or mold wafer, transferred to the article and easily separated from the template wafer. Thus, the attached protrusions may be, e.g., micro-bumps or micro pillars on an IC chip or substrate, test probes on a probe head, or one or more cantilevered membranes in a micro-machine or micro-sensor or other micro-electro-mechanical systems (MEMS) formed without undercutting the MEMS structure.

A method of forming surface protrusions on an article, and the article with the protrusions attached. The article may be an Integrated Circuit (IC) chip, a test probe for the IC chip or any suitable substrate or nanostructure. The surface protrusions are electroplated to a template or mold wafer, transferred to the article and easily separated from the template wafer. Thus, the attached protrusions may be, e.g., micro-bumps or micro pillars on an IC chip or substrate, test probes on a probe head, or one or more cantilevered membranes in a micro-machine or micro-sensor or other micro-electro-mechanical systems (MEMS) formed without undercutting the MEMS structure.

The present invention accurately distinguishes a soldering material less likely to oxidize. A Cu core ball has a Cu ball having a predetermined size, and a solder layer coating the Cu ball. The Cu ball provides a space between a semiconductor package and a printed circuit board. The Cu core ball has the soldering material having lightness greater than or equal to 62.5 in L*a*b* color space subsequent to a heating storage test performed for 72 hours in a temperature-controlled bath at 150 C. with a temperature of 25 C. and 40% humidity, and the soldering material, prior to the heating storage test, having lightness greater than or equal to 65 in the L*a*b* color space and yellowness less than or equal to 7.0 in the L*a*b* color space.

A core material including a core and a solder plating layer of a (SnBi)-based solder alloy made of Sn and Bi on a surface of the core. Bi in the solder plating layer is distributed in the solder plating layer at a concentration ratio in a predetermined range of, for example, 91.7% to 106.7%. Bi in the solder plating layer is homogeneous, and thus, a Bi concentration ratio is in a predetermined range over the entire solder plating layer including an inner circumference side and an outer circumference side in the solder plating layer.

A method of manufacturing a bonding structure includes (a) providing a substrate, wherein the substrate includes a top surface and at least one bonding pad disposed adjacent to the top surface of the substrate, at least one bonding pad having a sloped surface with a first slope; (b) providing a semiconductor element, wherein the semiconductor element includes at least one pillar, and at least one pillar has a sidewall with a second slope, wherein the absolute value of the first slope is smaller than the absolute value of the second slope; and (c) bonding at least one pillar to a portion of the sloped surface of corresponding ones of the at least one bonding pad.

A method of manufacturing a bonding structure includes (a) providing a substrate, wherein the substrate includes a top surface and at least one bonding pad disposed adjacent to the top surface of the substrate, at least one bonding pad having a sloped surface with a first slope; (b) providing a semiconductor element, wherein the semiconductor element includes at least one pillar, and at least one pillar has a sidewall with a second slope, wherein the absolute value of the first slope is smaller than the absolute value of the second slope; and (c) bonding at least one pillar to a portion of the sloped surface of corresponding ones of the at least one bonding pad.

A method for producing a stack of semiconductor devices and the stacked device obtained thereof are disclosed. In one aspect, the method includes providing a first semiconductor device comprising a dielectric layer with a hole, the hole lined with a metal layer and partially filled with solder material. The method also includes providing a second semiconductor device with a compliant layer having a metal protrusion through the compliant layer, the protrusion capped with a capping layer. The method further includes mounting the devices by landing the metal protrusion in the hole, where the compliant layer is spaced from the dielectric layer. The method includes thereafter reflowing the solder material, thereby bonding the devices such that the compliant layer is contacting the dielectric layer.

A method for producing a stack of semiconductor devices and the stacked device obtained thereof are disclosed. In one aspect, the method includes providing a first semiconductor device comprising a dielectric layer with a hole, the hole lined with a metal layer and partially filled with solder material. The method also includes providing a second semiconductor device with a compliant layer having a metal protrusion through the compliant layer, the protrusion capped with a capping layer. The method further includes mounting the devices by landing the metal protrusion in the hole, where the compliant layer is spaced from the dielectric layer. The method includes thereafter reflowing the solder material, thereby bonding the devices such that the compliant layer is contacting the dielectric layer.

A semiconductor chip, a display device or an electronic device includes a substrate, one or more conductive pads disposed on the substrate, and one or more bumps electrically connected to the one or more conductive pads, in which the one or more bumps includes a metal core, a polymer layer disposed over a surface of the metal core, and a conductive coating layer disposed over a surface of the polymer layer and electrically connected to the one or more conductive pads.

A semiconductor chip, a display device or an electronic device includes a substrate, one or more conductive pads disposed on the substrate, and one or more bumps electrically connected to the one or more conductive pads, in which the one or more bumps includes a metal core, a polymer layer disposed over a surface of the metal core, and a conductive coating layer disposed over a surface of the polymer layer and electrically connected to the one or more conductive pads.