Process for producing an electronic subassembly by low-temperature pressure sintering, comprising the following steps: arranging an electronic component on a circuit carrier having a conductor track, connecting the electronic component to the circuit carrier by the low-temperature pressure sintering of a joining material which connects the electronic component to the circuit carrier, characterized in that, to avoid the oxidation of the electronic component or of the conductor track, the low-temperature pressure sintering is carried out in a low-oxygen atmosphere having a relative oxygen content of 0.005 to 0.3%.

A resin shaping device configured to cure a resin placed in a mold in a state in which the mold is pressed against a substrate, the resin shaping device comprising: a substrate holding unit configured to hold the substrate in an orientation such that a forming face for forming a resin part on the substrate faces vertically downward; a head configured to hold the mold from vertically below; a head drive unit configured to cause the head to face a position for formation of a resin part on the substrate, and then cause vertically upward movement of the head so that the head approaches the substrate holding unit and presses the mold from vertically below the substrate; and a resin curing unit configured to cure the resin placed in the mold in a state in which the mold is pressed against the substrate.

The present invention relates to a laser reflow apparatus. More particularly, the present invention relates to a compression-type laser reflow apparatus with a vacuum chamber that enables mass processing by simultaneously pressuring and reflowing a plurality of electronic components by performing a laser reflow process by pressing with a light-transmitting pressing member and irradiating a laser beam inside the vacuum chamber, and that effectively prevents the generation of voids by fumes during soldering, so that the defect rate of the laser reflow process is greatly improved.

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 discloses a bonding cavity structure and a bonding method, the bonding cavity structure comprises an upper carrier and a lower carrier, a gas-flow forming mechanism, which comprises multiple open-close integrated arms, the integrated arms are provided with multiple nozzles facing to wafer bonding surfaces, and the nozzles are switched to gas nozzles or vacuum suction nozzles, a closed space is formed by all the integrated arms closed together with the carriers, all the nozzle located on a side of two wafers are set as the gas nozzles, which blow gas parallel to the wafer bonding surfaces, meanwhile, all the nozzles located on the other side of the two wafers are set as the vacuum suction nozzles, which suck the gas blown from the gas nozzle at corresponding position, a high-speed gas-flow is generated between the two wafers, so as to produce a low pressure of Bernoulli effect, the wafers are not only subjected to thrust forces from backsides, but tension forces between the bonding surfaces are also affected by uniform low pressure, which enhances force uniformity during bonding process, and reduces an impact of particles on the bonding surfaces in the closed space .

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.

The invention relates to a positioning device for positioning a substrate, in particular a wafer, comprising: a process chamber; a base body; a carrier element which comprises a support for supporting the substrate, the carrier element being arranged above the base body and formed movable in terms of distance from the base body; and a holder for an additional substrate, in particular an additional wafer or a mask, the holder being arranged opposite the carrier element; wherein there is, between the base body and the carrier element, a sealed-off cavity to which a pressure, in particular a negative pressure, can be applied so as to prevent undesired movement of the carrier element as a result of the action of an external force.

Production system for wafer bonding comprising modules for wet chemical wafer cleaning and surface passivation and vacuum modules with base pressure in the ultrahigh vacuum regime for the removal of surface passivation, wafer flipping and alignment, low temperature annealing and wafer bonding, with all modules integrated in the same tool and individually serviceable. Methods for oxide-free covalent semiconductor wafer bonding include wet chemistry and vacuum processing at low temperatures compatible with CMOS processed wafers.

A bonding device (100) bonds at least one component (C) to a substrate (B) using a metal material (M). The bonding device (100) includes a wall section (20), at least one pressing section (40), and a rotational shaft (30). The rotational shaft (30) is fixed to the wall section (20). Each pressing section (40) has an arm (42) and a presser (43) or a substrate supporting member (90). The arm (42) extends from the rotational shaft (30). The arm (42) pivots about the rotational shaft (30). The presser (43) presses the component (C). The substrate supporting member (90) is disposed on a reference surface (142). The substrate supporting member (90) supports the substrate (B). The component (C) is bonded to the substrate (B) through point contact of the presser (43) with the component (C) or point contact of the substrate supporting member (90) with the reference surface (142).

Disclosures of the present invention mainly describe a method for manufacturing perovskite solar cell module. At first, a laser scribing is adopted for forming multi transparent conductive films (TCFs) on a transparent substrate. Subsequently, by using a first mask, multi HTLs, active layers, and ETLs are sequentially formed on the TCFs. Consequently, by the use of a second make, each of the ETLs is formed with an electrically connecting layer thereon, such that a perovskite solar cell module comprising a plurality of solar cell units is hence completed on the transparent substrate. It is worth explaining that, during the whole manufacturing process, each of the solar cell units is prevented from receiving bad influences that are provided by laser scribing or manufacture environment, such that each of the solar cell units is able to exhibit outstanding photoelectric conversion efficiency.