Provided is an equipment front end module (EFEM) including a base configured to communicate with a processor, a tray port on the base, the tray port being configured to load a tray including a stub and a grid holder, a working robot configured to move in a direction on the base, and grasp and convey the stub in the tray and the grid holder in the tray, and a shuttle port on the base, the shuttle port including a first groove configured to fix the stub, and a second groove configured to fix the grid holder, wherein the working robot is further configured to convey the stub to the first groove and convey the grid holder to the second groove.

A method for securing and verifying semiconductor wafers during fabrication includes receiving a semiconductor wafer after a layer of features has been patterned thereon. At least one security mark is formed at one or more locations embedded within a backside of the semiconductor wafer by implanting an inert species at the one or more locations. At a subsequent point in fabrication and/or after fabrication of the semiconductor wafer has completed the backside of the wafer is inspected for detection of the at least one security mark. If the at least one security mark is not detected at an expected location within the backside of the semiconductor wafer a determination is made that the semiconductor wafer has been compromised.

A module for operating a carrier of one or more substrates to be treated in a vacuum deposition method includes a frame provided with a plate receiving, on a first side, an electronic assembly comprising radio transmitter/receiver electronics, a processor card, motor controller electronics and a battery for supplying power to the module. The processor card has a program memory with a program for controlling the motor controller electronics according to data received from a remote apparatus provided with a radio transmitting/receiving device for communicating with the module's radio transmitter/receiver electronics and, on a second side, a device for operating the carrier, which device is provided with a first motor for rotating the carrier about a first axis parallel to the plate and with a second motor for rotating the carrier about a second axis perpendicular to the plate.

A device may detect a semiconductor wafer to be transferred from a source wafer carrier to a target wafer carrier, and may cause a light source to illuminate the semiconductor wafer. The device may cause a camera to capture images of the semiconductor wafer after the light source illuminates the semiconductor wafer, and may perform image recognition of the images of the semiconductor wafer to determine whether an edge of the semiconductor wafer is damaged. The device may cause the semiconductor wafer to be provided to the source wafer carrier when the edge of the semiconductor wafer is determined to be damaged, and may cause the semiconductor wafer to be provided to the target wafer carrier when the edge of the semiconductor wafer is determined to be undamaged.

Disclosed is an article transfer apparatus. The article transfer apparatus includes a vehicle that travels along a driving rail installed on a ceiling, a hoist module that picks up an article-to-be-transferred, a vehicle body, on which the hoist module is mounted and which is connected to the vehicle, a drop preventing member provided in the vehicle body, and that prevents the article-to-be-transferred from dropping while the vehicle travels, and a controller that receives loading/unloading information of the article-to-be transferred to determine a size of the article-to-be-transferred, and to drive the drop preventing member according to a size of the article-to-be transferred.

A conveyance system includes storage racks that are provided near or adjacent to semiconductor manufacturing devices and store therein objects to be conveyed, a stacker crane that carries the objects into and out of the storage racks, vehicles that convey the objects, an ID tag reader that is provided to the stacker crane and reads ID tags of the objects; and a controller that is configured or programmed to, when identification information acquired by the ID tag reader R coincides with identification information contained in a conveyance command of an object, control the stacker crane to convey the object to a destination specified in the conveyance command. At least one section of each storage rack allows a gripper of each vehicle to take in and out the objects.

In certain embodiments, a system includes: a source lane configured to move a first die container between a load port and a source lane staging area; an inspection sensor configured to produce a sensor result based on a die on the first die container; a pass target lane configured to move a second die container between a pass target lane out port and a pass target lane staging area; a fail target lane configured to move a third die container between a fail target lane out port and a fail target lane staging area; and a conveyor configured to move the die from the first die container at the source lane staging area to either the second die container at the pass target lane staging area or the fail target lane staging area based on the sensor result.

Proposed are article storage equipment in a semiconductor fabrication facility, the article storage equipment being capable of power supply with a more simplified configuration, and a logistics system of a semiconductor fabrication facility including the same. Article storage equipment in a semiconductor fabrication facility according to one aspect includes a storage unit installed around a rail that provides a travel route of a transport vehicle and configured to store a transport container in which a wafer is accommodated, a purge unit configured to supply an inert gas into the transport container, a control unit configured to identify the transport container stored in the storage unit and control the purge unit to supply the inert gas into the transport container, and a power supply unit configured to supply a current induced from a power supply cable installed along the rail to the control unit.

Apparatus and methods for handling die carriers are disclosed. In one example, a disclosed apparatus includes: a load port configured to load a die carrier operable to hold a plurality of dies into a processing tool; and a lane changer coupled to the load port and configured to move at least one die in the die carrier to an input of the processing tool and transfer the at least one die into the processing tool for processing the at least one die.

Disclosed are methods and systems of controlling the placement of micro-objects on the surface of a micro-assembler. Control patterns may be used to cause electrodes of the micro-assembler to generate dielectrophoretic (DEP) and electrophoretic (EP) forces which may be used to manipulate, move, position, or orient one or more micro-objects on the surface of the micro-assembler. The control patterns may be part of a library of control patterns.