A lithographic apparatus comprising: a clamping surface for supporting a substrate, wherein a property of the clamping surface is defined by at least one clamping surface parameter, and wherein the property of the clamping surface has been selected to exhibit low wear; a clamping apparatus for actuating a clamping operation between the clamping surface and the substrate, wherein the clamping operation is defined at least in part by at least one interface characteristic between the clamping surface and the substrate; and a processing station, operable to apply an adjustment to a first property of the substrate to optimize at least one interface characteristic of a particular clamping operation in dependence on the clamping surface parameter and at least one substrate surface parameter which defines a second property of the substrate.

A method for monitoring flatness of a wafer table includes: acquiring a yield and original focus data of a wafer in real time; obtaining an edge flatness curve of a wafer table based on the original focus data; obtaining a yield curve of the wafer based on the yield of the wafer; obtaining a trend diagram of the edge flatness and the yield over time based on the edge flatness curve and the yield curve; and determining, based on the trend diagram, an edge flatness value of the wafer table when the wafer table is replaced.

A substrate holding board includes a first layer and a second layer forming an interfacial surface with the first layer. The first layer and the second layer contain diamond-like carbon. A refractive index of the first layer in a wavelength is higher than a refractive index of the second layer in the wavelength. A distance from the second layer to a topmost surface of the substrate holding board is smaller than a thickness of the first layer.

Methods and arrangement for clamping substrates to a support using adhesive material area disclosed. The method comprises providing a support comprising a first surface defining a plane; applying adhesive material on at least portions of the first surface; and placing the substrate onto the adhesive material, wherein the adhesive material forms a plurality of support locations supporting the substrate. Preferably the adhesive material is cured at least partly during the application of a substantially uniformly distributed force to the substrate in the direction of the support. The arrangements comprise a support comprising a first surface, for supporting the substrate via adhesive material, whereby the first surface defines a plane. Preferably it also comprises an arrangement for providing electromagnetic radiation, thermal energy, and/or a chemical substance to the adhesive material, and an arrangement for providing a substantially uniformly distributed force to the substrate in the direction of the support.

A substrate with a backside surface configured to provide a friction switch when the substrate is loaded onto a substrate holder in a substrate-loading cycle, wherein the substrate backside surface has a molecular assembly including at least one high-interaction region and at least one low-interaction region. Further, there is provided methods using such a substrate and methods for creating such a substrate.

A substrate holder for a lithographic apparatus has a main body having a thin-film stack provided on a surface thereof. The thin-film stack forms an electronic or electric component such as an electrode, a sensor, a heater, a transistor or a logic device, and has a top isolation layer. A plurality of burls to support a substrate are formed on the thin-film stack or in apertures of the thin-film stack.

A method for processing a semiconductor wafer is provided. The method includes transferring the semiconductor wafer above a wafer placement device having a plate to align an edge of the semiconductor wafer with a first buffer member positioned in a peripheral region of the plate and to align a center of the semiconductor wafer with a second buffer member positioned in a central region of the plate. Each of the first buffer member and the second buffer member has a stiffness that is less than that of the plate. The method further includes lowering down the semiconductor wafer to place the semiconductor wafer over the plate.

A method for unloading a substrate from a support table configured to support the substrate, the method including: supplying gas to a gap between a base surface of the support table and the substrate via a plurality of gas flow openings in the support table, wherein during an initial phase of unloading the gas is supplied through at least one gas flow opening in an outer region of the support table and not through any gas flow opening in a central region of the support table radially inward of the outer region, and during a subsequent phase of unloading the gas is supplied through at least one gas flow opening in the outer region and at least one gas flow opening in the central region.

A positioning apparatus includes a guide, a movable member capable of moving in a first direction while being guided by the guide, and a driver configured to drive the movable member in the first direction. The driver includes a feed screw extending in the first direction, a nut configured to threadably engage with the feed screw and move in the first direction along with a rotation of the feed screw, and a connecting device configured to connect the nut and the movable member. The connecting device includes a hollow rod with one end connected to the movable member and the other end connected to the nut, and the feed screw is inserted into a hollow portion of the rod.

In an embodiment, an apparatus includes an energy source, a support platform for holding a wafer, an optical path extending from the energy source to the support platform, and a photomask aligned such that a patterned major surface of the photomask is parallel to the force of gravity, where the optical path passes through the photomask, where the patterned major surface of the photomask is perpendicular to a topmost surface of the support platform.