A clamping appliance of a reticle inner pod comprises: two clamping seats and a power member. The two clamping seats face each other in a width direction. The power member adjusts a distance of the two clamping seats in the width direction. The two clamping seats each include a bottom wall, two side walls, a first step and a second step. The two side walls are respectively disposed at two ends of the bottom wall. The first step and the second step are sequentially arranged above the bottom wall along the width direction. The two clamping seats each further include two eaves, the two eaves are respectively perpendicularly connected to the two side walls, so that the eave, the side wall and the bottom wall are clamped to form a cladding space with three-sided cladding.

A clamping appliance of a reticle inner pod comprises: two clamping seats and a power member. The two clamping seats face each other in a width direction. The power member adjusts a distance of the two clamping seats in the width direction. The two clamping seats each include a bottom wall, two side walls, a first step and a second step. The two side walls are respectively disposed at two ends of the bottom wall. The first step and the second step are sequentially arranged above the bottom wall along the width direction. The two clamping seats each further include two eaves, the two eaves are respectively perpendicularly connected to the two side walls, so that the eave, the side wall and the bottom wall are clamped to form a cladding space with three-sided cladding.

While a wafer stage moves linearly in a Y-axis direction, surface position information of a wafer surface at a plurality of detection points set at a predetermined interval in an X-axis direction is detected by a multipoint AF system, and by a plurality of alignment systems arranged in a line along the X-axis direction, marks at different positions on the wafer are each detected, and a part of a chipped shot of the wafer is exposed by a periphery edge exposure system. This allows throughput to be improved when compared with the case when detection operation of the marks, detection operation of the surface position information (focus information), and periphery edge exposure operation are performed independently.

Provided herein are approaches for processing reticle blanks. In one approach, a reticle processing system includes a support assembly having a plate coupled to a frame, and a carrier assembly coupled to the support assembly. In one approach, the carrier assembly includes a carrier base coupled to the plate, a reticle disposed over the carrier base, and a carrier shield disposed over the reticle, wherein the carrier shield may include a central opening formed therein, allowing for placement and extraction of the reticle. In one approach, when the carrier assembly is placed atop the support assembly, a plurality of pins extend from the plate through corresponding openings in the carrier base, the plurality of pins supporting the carrier assembly so the carrier base, the reticle, and the carrier shield are each independently supported and vertically separated from one another.

Embodiments described herein provide a method for cleaning contamination from sensors in a lithography tool without requiring recalibrating the lithography tool. More particularly, embodiments described herein teach cleaning the sensors using hydrogen radicals for a short period while the performance drifting is still above the drift tolerance. After a cleaning process described herein, the lithography tool can resume production without recalibration.

A lithographic apparatus including: a projection system to project radiation onto a substrate supported on a substrate stage, during an exposure phase; a sensing system to sense a property of the substrate on the stage during a sensing phase; and a positioning system to determine a position of the stage relative to a reference system via a radiation path between the stage and the reference system, wherein the apparatus is configured to control stage movement relative to the reference system in the sensing phase and to control other movement relative to the reference system during the exposure phase; the stage or reference system having an outlet to provide a gas curtain to reduce ingress of ambient gas into the path; and the apparatus is operative such that a characteristic of the gas curtain is different in at least part of the sensing phase compared to in the exposure phase.

An apparatus and method for performing a measurement operation on a substrate in accordance with one or more substrate alignment models. The one or more substrate alignment models are selected from a plurality of candidate substrate alignment models. The apparatus, which may be a lithographic apparatus, includes an external interface which enables selection of the substrate alignment model(s) and/or alteration of the substrate alignment model(s) prior to the measurement operation.

The invention relates to an assembly for enclosing a target processing machine. The assembly comprises an enclosure and a transfer unit. The enclosure comprises a base plate for arranging said target processing machine thereon, side wall panels, which are fixed to said base plate, and a top wall panel which is fixed to said side wall panels. In addition, the enclosure comprises an access opening in a side wall of the enclosure. The transfer unit comprising one or more transfer elements for moving the transfer unit with respect to the base plate. The transfer unit further comprises a door panel which is arranged for closing the access opening, wherein the door panel is movably mounted to the transfer unit by means of a flexible coupling which allows a movement of the door panel with respect to the transfer unit at least in a direction towards and/or away from the enclosure.

An electromagnetic actuator includes a coil assembly including a coil; a magnet assembly including a first and a second magnet unit, each magnet unit including a magnetic yoke and a plurality of permanent magnets mounted to the magnetic yoke, the first and second magnet unit forming a magnetic circuit for receiving the coil assembly and, upon energizing the coil, generating a force in a first direction; and a holder for holding the magnet units, wherein a weight ratio of the magnet assembly over the coil assembly is smaller than the weight ratio of the magnet assembly over the coil assembly when the ratio of force over electrical power is maximized.

A lithographic apparatus including: a projection system to project radiation onto a substrate supported on a substrate stage, during an exposure phase; a sensing system to sense a property of the substrate on the stage during a sensing phase; and a positioning system to determine a position of the stage relative to a reference system via a radiation path between the stage and the reference system, wherein the apparatus is configured to control stage movement relative to the reference system in the sensing phase and to control other movement relative to the reference system during the exposure phase; the stage or reference system having an outlet to provide a gas curtain to reduce ingress of ambient gas into the path; and the apparatus is operative such that a characteristic of the gas curtain is different in at least part of the sensing phase compared to in the exposure phase.