In an embodiment, a system includes: a tool port of a semiconductor processing tool; a processing port with an internal processing port location and an external processing port location; a robot configured to move a die vessel between the internal processing port location and the tool port; and an actuator configured to move the die vessel between the internal processing port location and the external processing port location.

The present invention is an IC chip mounting apparatus including: a conveyor configured to convey an antenna continuous body on a conveying surface, the antenna continuous body having a base material and plural inlay antennas continuously formed on the base material; an IC chip placement unit configured to place an IC chip on a photo-curable adhesive that is located on a reference position of each antenna in the antenna continuous body; and a light irradiator configured to irradiate, with light, the adhesive of each antenna of the antenna continuous body that is conveyed by the conveyor, wherein the light irradiator is configured to irradiate the adhesive of each antenna with the light, while the IC chip on the adhesive is pressed to the antenna.

A compound fork device includes a first prong and a second prong spaced apart from the first prong. Each of the first and second prongs has an upper surface and a lower surface which is depressed relative to the upper surface. The upper surfaces of the first and second prongs are configured to cooperatively retain a first type container. The lower surfaces of the first and second prongs are configured to cooperatively retain a second type container having a configuration different from that of the first type container. A method and a system using the compound fork device are also disclosed.

A manufacturing method of a chip-attached substrate includes preparing a stacked substrate including multiple chips, a first substrate to which the multiple chips are temporarily bonded, and a second substrate bonded to the first substrate with the multiple chips therebetween; and separating the multiple chips bonded to the first substrate and the second substrate from the first substrate to bond the multiple chips to one surface of a third substrate including a device layer.

A system, includes, a semiconductor processing unit, an Automated Materials Handling System (AMHS) vehicle, and a warehouse apparatus, wherein the warehouse apparatus comprises at least one input port, at least one output port, and at least one load/unload port, wherein the warehouse apparatus is configured to perform one of the following: receiving a plurality of tray cassette containers from the AMHS vehicle at the at least one input port, transporting at least one tray cassette in each of a plurality of tray cassette containers to the at least one load/unload port via the at least one input port, transporting at least one first tray from the at least one tray cassette to the semiconductor processing unit via a tray feeder conveyor, and receiving at least one second tray from the semiconductor processing unit via the tray feeder conveyor.

An adsorption device includes a substrate and a magnetic film on a surface of the substrate. The substrate has magnetic properties and is capable of generating magnetic field. The magnetic film partially covers the surface. The magnetic film generates a magnetic field having a direction that is opposite to a direction of the magnetic field generated by the substrate. Portions of the surface of the substrate not covered by the magnetic film form positions to attract and adsorb target objects, and other portion of the surface of the substrate covered by the magnetic film is not able to attract any target object.

A method of transferring a micro device using a micro device transfer head is provided. The micro device transfer head includes a base arm, a first side arm and a second side arm, and the micro device is fabricated on a substrate. The method includes moving the first side arm within a sensing range of the micro device, charging the first side arm for drawing the micro device away from the substrate to move towards a space between the first side arm and the second side arm, and shortening a distance between the first side arm and the second side arm for clamping the micro device.

A system, includes, a semiconductor processing unit, an Automated Materials Handling System (AMHS) vehicle, and a warehouse apparatus, wherein the warehouse apparatus comprises at least one input port, at least one output port, and at least one load/unload port, wherein the warehouse apparatus is configured to perform one of the following: receiving a plurality of tray cassette containers from the AMHS vehicle at the at least one input port, transporting at least one tray cassette in each of a plurality of tray cassette containers to the at least one load/unload port via the at least one input port, transporting at least one first tray from the at least one tray cassette to the semiconductor processing unit via a tray feeder conveyor, and receiving at least one second tray from the semiconductor processing unit via the tray feeder conveyor.

The present invention relates to a method of manufacturing a display device, and more particularly, to a chip dispenser for supplying a micro-LED. The present invention provides a chip dispenser including a body part for accommodating the fluid and the semiconductor light emitting device, and discharging the accommodated fluid and the semiconductor light emitting device, a pressure controller for varying the pressure inside the body; and a stirring part disposed in at least one of the inside and outside of the body, agitating the fluid accommodated in the body and the pressure controller increases the internal pressure of the body part so that the fluid and the semiconductor light emitting device are discharged to the outside in a state in which the agitating part stirs the fluid.

A mask arrangement for masking a substrate in a processing chamber is provided. The mask arrangement includes a mask frame having one or more frame elements and is configured to support a mask device, wherein the mask device is connectable to the mask frame; and at least one actuator connectable to at least one frame element of the one or more frame elements, wherein the at least one actuator is configured to apply a force to the at least one frame element.