A bonding system for bonding a semiconductor element to a substrate is provided. The bonding system includes a bond head assembly for bonding a semiconductor element to a substrate at a bonding area of the bonding system; a reducing gas delivery system for providing a reducing gas to the bonding area during bonding of the semiconductor element to the substrate; and a gas composition analyzer configured for continuously monitoring a composition of the reducing gas during operation of the bonding system.

A method includes picking up a first package component, removing an oxide layer on an electrical connector of the first package component, placing the first package component on a second package component after the oxide layer is removed, and bonding the first package component to the second package component.

A method for producing a joined structure according to the present invention includes: a reflow step of heating a first member and a solder material while keeping them in contact with each other in a reflow chamber to melt a solder alloy constituting the solder material, the reflow step including: a first reflow step of melting the solder alloy with an atmosphere in the reflow chamber reduced to a first pressure P.sub.1 lower than the atmospheric pressure; and a second reflow step of, after the first reflow step, melting the solder alloy with the atmosphere in the reflow chamber reduced to a second pressure P.sub.2 lower than the first pressure P.sub.1.

An approach to provide a method of joining a semiconductor chip to a semiconductor substrate, the approach includes depositing a nanoparticle paste and aligning each of one or more solder contacts on a semiconductor chip to a substrate bond pad. The approach includes sintering, in a reducing gaseous environment, the nanoparticle paste to connect the semiconductor chip to a semiconductor substrate bond pad.

The present disclosure is directed to a compact vertical oven for reflow of solder bumps for backend processes in semiconductor wafer assembly and packaging. This disclosure describes a vertical oven which uses a plurality of wafers (e.g., an example value is 50-100 wafers) in a batch with controlled injection of the reducing agent (e.g. formic acid), resulting in a process largely free of contamination. This disclosure describes controlled formic acid flow through a vertical system using laminar flow technology in a sub-atmospheric pressure environment, which is not currently available in the industry. The efficacy of the process depends on effective formic acid vapor delivery, integrated temperature control during heating and cooling, and careful design of the vapor flow path with exhaust. Zone-dependent reaction dynamics managed by vapor delivery process, two-steps temperature ramp control, and controlled cooling process and formic acid content ensures the effective reaction without any flux.

The present invention provides a method for manufacturing an electronic device including a base material that has an exposed metal portion on a surface of the base material and an electronic component that is provided on the base material. The method includes a flux treatment step of treating the exposed metal portion with a flux by bringing the exposed metal portion into contact with the flux and an introduction step of introducing a resin composition such that the resin composition comes into contact with a surface of the exposed metal portion treated with the flux. The flux contains a rosin, an activator, and a solvent. The content of the rosin is equal to or greater than 1 part by mass and equal to or smaller than 18 parts by mass with respect to 100 parts by mass of the flux. The percent change in mass of the flux before and after a heating treatment is equal to or lower than 21% by mass. The resin composition contains an epoxy resin and a phenolic resin curing agent. In a case where SP1 represents a Hansen's method-based average solubility parameter of a resin group consisting of the epoxy resin and the phenolic resin curing agent in the resin composition, and Mn1 represents a number average molecular weight of the resin group, SP1 and Mn1 satisfy Mn1≤210×SP1−4,095.

A bonding system for bonding a semiconductor element to a substrate is provided. The bonding system includes a substrate oxide reduction chamber configured to receive a substrate. The substrate includes a plurality of first electrically conductive structures. The substrate oxide reduction chamber is configured to receive a reducing gas to contact each of the plurality of first electrically conductive structures. The bonding system also includes a substrate oxide prevention chamber for receiving the substrate after the reducing gas contacts the plurality of first electrically conductive structures. The substrate oxide prevention chamber has an inert environment when receiving the substrate. The bonding system also includes a reducing gas delivery system for providing a reducing gas environment during bonding of a semiconductor element to the substrate.

A bonding system for bonding a semiconductor element to a substrate is provided. The bonding system includes a substrate oxide reduction chamber configured to receive a substrate. The substrate includes a plurality of first electrically conductive structures. The substrate oxide reduction chamber is configured to receive a reducing gas to contact each of the plurality of first electrically conductive structures. The bonding system also includes a substrate oxide prevention chamber for receiving the substrate after the reducing gas contacts the plurality of first electrically conductive structures. The substrate oxide prevention chamber has an inert environment when receiving the substrate. The bonding system also includes a reducing gas delivery system for providing a reducing gas environment during bonding of a semiconductor element to the substrate.

An imaging device includes a first semiconductor element including at least one bump pad that has a concave shape. The at least one bump pad includes a first metal layer and a second metal layer on the first metal layer. The imaging device includes a second semiconductor element including at least one electrode. The imaging device includes a microbump electrically connecting the at least one bump pad to the at least one electrode. The microbump includes a diffused portion of the second metal layer, and first semiconductor element or the second semiconductor element includes a pixel unit.

A method of making an assembly can include juxtaposing a top surface of a first electrically conductive element at a first surface of a first substrate with a top surface of a second electrically conductive element at a major surface of a second substrate. One of: the top surface of the first conductive element can be recessed below the first surface, or the top surface of the second conductive element can be recessed below the major surface. Electrically conductive nanoparticles can be disposed between the top surfaces of the first and second conductive elements. The conductive nanoparticles can have long dimensions smaller than 100 nanometers. The method can also include elevating a temperature at least at interfaces of the juxtaposed first and second conductive elements to a joining temperature at which the conductive nanoparticles can cause metallurgical joints to form between the juxtaposed first and second conductive elements.