A semiconductor manufacturing apparatus according to an embodiment includes a chuck configured to receive a carrier thereon, a carrier contact device configured to contact the carrier on the chuck, and a bonding head configured to transfer a semiconductor die to the carrier and configured to attach the semiconductor die on the carrier. The chuck includes a chuck reference key positioned at an edge portion thereof. The carrier contact device includes a contact position recognition key. The semiconductor manufacturing apparatus also includes a camera configured to obtaining images of the chuck reference key and the contact position recognition key.

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.

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.

A cell of fluidic assembly of microchips on a substrate, including: a base having its upper surface intended to receive the substrate; a body laterally delimiting a fluidic chamber above the substrate; and a cover closing the fluidic chamber from its upper surface, wherein the body comprises first and second nozzles respectively emerging onto opposite first and second lateral edges of the fluidic chamber, each of the first and second nozzles being adapted to injecting and/or sucking in a liquid suspension of microchips into and/or from the fluidic chamber, in a direction parallel to the mean plane of the substrate.

The present disclosure, in some embodiments, relates to a workpiece bonding apparatus. The workpieces bonding apparatus includes a first substrate holder having a first surface configured to receive a first workpiece, and a second substrate holder having a second surface configured to receive a second workpiece. A vacuum apparatus is positioned between the first substrate holder and the second substrate holder and is configured to selectively induce a vacuum between the first surface and the second surface. The vacuum is configured to attract the first surface and the second surface toward one another.

The present invention relates to a reel-to-reel layer reflow method, which emits a uniformized laser beam, which can easily adjust the emission area, and which is for the purpose of improving productivity. An embodiment of the present invention provides a reel-to-reel layer reflow method comprising the steps of: a) transferring a substrate, which has been wound in a roll type, to one side while unwinding the same; b) forming a solder portion on the substrate; c) seating an emission target element on the solder portion and seating a non-emission target element on the substrate; d) surface-emitting a laser beam to the solder portion, on which the emission target element is seated, such that the emission target element is attached to the substrate; e) inspecting the substrate structure manufactured through said step d); and f) winding the substrate structure in a roll type.

A method of monitoring gas byproducts of a bonding system is provided. The method includes: providing a plurality of bonding systems, each of the bonding systems including a reducing gas delivery system for use in connection with a bonding operation, each of the bonding systems being configured for exhausting gas byproducts; connecting each of the bonding systems to a monitoring device using a respective gas delivery path; and monitoring a composition of at least a portion of the gas byproducts with the monitoring device.

An apparatus for aligning dipoles is provided. The apparatus includes: an electric field forming unit including a stage and a probe unit, the probe unit being configured to form an electric field on the stage; an inkjet printing device including an inkjet head, the inkjet head being configured to spray ink including a solvent and dipoles dispersed in the solvent onto the stage; a light irradiation device configured to irradiate light onto the stage; and a temperature control device including a temperature control unit, the temperature control unit being configured to control a temperature of the solvent sprayed on the stage.

A method for use in the spatial registration of first and second objects comprises fixing the first and second objects to the same motion control stage in an unknown spatial relationship, using an imaging system to acquire an image of the first object, determining a position and orientation of the first object in a frame of reference of the motion control stage based at least in part on the acquired image of the first object, using the imaging system to acquire an image of the second object, and determining a position and orientation of the second object in the frame of reference of the motion control stage based at least in part on the acquired image of the second object. The method may be used in the spatial registration of first and second objects and, in particular though not exclusively, for use in the spatial registration of optical or electronic components relative to one another, or for use in the alignment of a first object such as an optical or electronic component relative to a second object such as a feature, a structure, a target area or a target region defined on a substrate or a wafer.

A system for reflowing a semiconductor workpiece including a stage, a first vacuum module and a second vacuum module, and an energy source is provided. The stage includes a base and a protrusion connected to the base, the stage is movable along a height direction of the stage relative to the semiconductor workpiece, the protrusion operably holds and heats the semiconductor workpiece, and the protrusion includes a first portion and a second portion surrounded by and spatially separated from the first portion. The first vacuum module and the second vacuum module respectively coupled to the first portion and the second portion of the protrusion, and the first vacuum module and the second vacuum module are operable to respectively apply a pressure to the first portion and the second portion. The energy source is disposed over the stage to heat the semiconductor workpiece held by the protrusion of the stage.