Methods of forming structures including a stress management layer for photolithography and structures including the stress management layer are disclosed. Further disclosed are systems for depositing a stress management layer. Exemplary methods include forming the stress management layer using one or more of plasma-enhanced cyclic (e.g., atomic layer) deposition and plasma-enhanced chemical vapor deposition.

Methods and associated apparatus for reconstructing a free-form geometry of a substrate, the method including: positioning the substrate on a substrate holder configured to retain the substrate under a retaining force that deforms the substrate from its free-form geometry; measuring a height map of the deformed substrate; and reconstructing the free-form geometry of the deformed substrate based on an expected deformation of the substrate by the retaining force and the measured height map.

A carrier system and method carries an object to an object mounting member provided with an object mounting section. The system includes: a measurement device which obtains information related to a flatness of the object; a carrier member that carries the object; and a controller which controls a driving speed of the carrier member using the information related to the flatness of the object obtained by the measurement device.

A system having a sub-system that is configured to change a thermal condition of a physical component from a set-point to a new set-point, wherein the sub-system includes: a mixer operative to receive a first conditioning fluid having a first temperature and a second conditioning fluid having a second temperature different from the first temperature, and operative to supply to the physical component a mix of the first conditioning fluid and the second conditioning fluid; and a controller configured to control the mixer in dependence on the new set-point. Also a method of operating a lithographic apparatus as well as a device manufactured using the system described herein or according to methods described herein.

In some embodiments, a reticle structure is provided. The reticle structure includes a reticle stage and a reticle mounted on the reticle stage. The reticle stage includes plural first burls and plural second burls, in which the second burls are disposed on a center of the reticle stage and the first burls disposed on an edge of the reticle stage such that the first burls surround the second burls. The reticle includes a base material and a pattern layer overlying the base material. The base material is secured on the first and second burls of the reticle stage. The pattern layer includes plural first gratings, and each of the first burls is vertically aligned with one of the first gratings.

The present disclosure is directed to EUV mask inspection tools including a source assembly that generates a EUV beam, a detector assembly having a projection optics system, a processor, a movable stage supporting a patterned mask, a stage control system, and a processor programmed to set the height for the stage based on instructions of a first program module that analyzes and combines mask pattern data and mask layout information to generate an out-of-plane distortion map. In an aspect, a second program module generates instructions to analyze inspection results outputted by the inspection tool to generate a defocus characterization map. In a further aspect, a present method provides predictive data and actual measured data to determine stage heights for use by a present mask inspection tool for inspection of patterned EUV masks to obtain results that compensate for defocusing to due to bowing of the patterned EUV mask.

An air-bearing chuck includes a nozzle portion and a gas channel portion. The nozzle portion is provided with a plurality of support force nozzles for generating an air cushion on a top surface of the nozzle portion. The gas channel portion includes a first gas channel configured to transmit a first gas to the plurality of support force nozzles to provide support force. Embodiments of the present application can implement that the first gas channel transmits the first gas to the plurality of support force nozzles to provide support force, and an air cushion is generated on the top surface of the nozzle portion by regulating gas flow of the first gas in the first gas channel, thereby keeping a supported object supported by the air cushion stably floating up on one side, away from the top surface of the nozzle portion, of the air cushion.

A method for semiconductor fabrication includes mounting a wafer onto a first wafer table. The first wafer table includes a first set of pins that support the wafer, the first set of pins having a first pitch between adjacent pins. The method further includes forming a first set of overlay marks on the wafer; and transferring the wafer onto a second wafer table. The second wafer table includes a second set of pins having a second pitch between adjacent pins. The second set of pins are individually and vertically movable, and the second pitch is smaller than the first pitch. The method further includes moving a portion of the second set of pins such that a remaining portion of the second set of pins supports the wafer and the remaining portion has the first pitch between adjacent pins.

Method and system for defining basis functions for fitting distortions of profiles of objects in a batch, that has undergone a fabrication process, in a manner adaptable to the fabrication process to reduce the errors between profiles approximated with the use of such basis functions and actual object profiles. Process-specific individual basis functions are defined based on spatially-dense measurement of objects from training sub-set of the batch and applying learning algorithm to results of such measurement. Advantages of process-adaptable basis functions over generic basis functions for fitting distortion shapes of objects include higher accuracy of fitting either at larger or a fewer locations across the object.

Systems, apparatuses, methods, and computer program products are provided for determining a free form flatness of a substrate table. An example system can include a substrate table that includes a first substrate table surface and a grounded substrate table electrical connection configured to ground the substrate table. The system can further include a substrate that includes a semiconducting layer, a thermally-grown insulating layer, a first substrate surface disposed on the insulating layer, and a substrate electrical connection configured to transmit a voltage to the semiconducting layer. The system can further include a metrology system configured to apply a voltage to the substrate electrical connection to electrostatically clamp the substrate to the substrate table, measure a flatness of the first substrate surface, and determine a free form flatness of the first substrate table surface based on the measured flatness of the first substrate surface.