Abstract: Method and system for calibrating exposure system for manufacturing of integrated circuits. According to an embodiment, the present invention provides a method for determining one or more focus parameters for an exposure system. As an example, the exposure system is used for forming patterns on semiconductor wafer. The method includes a step for providing a semiconductor wafer. The semiconductor wafer is characterized by a diameter. The method also includes a step for forming a plurality of patterns using the exposure system on the semiconductor wafer. As an example, each of the plurality of patterns being associated with a focus reference value (e.g., focus distance, focus angle, etc.). The method additionally includes a step for determining a plurality of shift profiles, and each of the shift profile is associated one of the plurality of patterns.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes a primary light source, a system pupil surface and a mirror array. The mirror array is arranged between the primary light source and the system pupil surface. The mirror array includes a plurality of adaptive mirror elements. Each mirror element includes a mirror support and a reflective coating. Each mirror element is configured to direct light produced by the primary light source towards the system pupil surface. The mirror elements can be tiltably mounted with respect to a support structure. The mirror elements include structures having a different coefficient of thermal expansion and being fixedly attached to one another. A temperature control device is configured to variably modify the temperature distribution within the structures to change the shape of the mirror elements.

Abstract: Exposure areas are wholly overlapped by moving a gradient refractive index lens array in a direction perpendicular to a scanning direction, or by providing a plurality of gradient refractive index lens arrays, an optical filter having a density distribution of lightness and darkness to compensate light transmission nonuniformity of the gradient refractive index lens array is arranged, or an opening control plate for limitedly using only of a uniform portion is provided. Two or more means may be simultaneously provided among the aforementioned mean. Moreover, any one of a microscopic transmission shutter array, a microscopic reflection shutter array, and a microscopic light emitter array is used instead of a mask, or an illuminating device and the mask.

Abstract: An immersion lithographic apparatus has a pressure sensor configured to measure the pressure of immersion liquid in a space between the substrate and a projection system. A control system is responsive to a pressure signal generated by the pressure sensor and controls a positioner to exert a force on the substrate table to compensate for the force exerted on the substrate table by the immersion liquid.

Abstract: A lithographic method includes exposing a first layer of material to a radiation beam to form a first pattern feature in the first layer, the first pattern feature having sidewalls, and a focal property of the radiation beam being controlled to control a sidewall angle of the sidewalls; providing a second layer of material over the first pattern feature to provide a coating on sidewalls of the first pattern; removing a portion of the second layer, leaving a coating of the second layer of material on sidewalls of the first pattern; removing the first pattern formed from the first layer, leaving on the substrate at least a part of the second layer that formed a coating on sidewalls of that first pattern, the part of the second layer left forming second pattern features in locations adjacent to the locations of sidewalls of the removed first pattern feature.

Abstract: When a wafer on a fine movement stage supported by a coarse movement stage is exposed via a projection optical system with an illumination light at an exposure station, a position of the fine movement stage within an XY plane is measured with good precision by a measurement system. Further, when an alignment to a wafer on a fine movement stage supported by a coarse movement stage is performed at a measurement station, a position of the fine movement stage within an XY plane is measured with good precision by a measurement system.

Abstract: An optical nanolithography system and a method for optical nanolithography using a tilting transparent medium are disclosed. Initially, a pattern is exposed on a substrate at a first location by sending electromagnetic energy through the tilting transparent medium at a first angle. Then, the angle of the tilting transparent medium is changed to a second angle that is different from the first angle. Next, the pattern is exposed on the substrate at a second location by sending electromagnetic energy through the tilting transparent medium at the second angle. The second location is different from and partially overlaps with the first location. Then, the substrate is developed so that overlapping regions of the substrate exposed by the pattern at the first location and at the second location are developed differently from non-overlapping regions of the substrate exposed by the pattern only at the first location or at the second location.

Abstract: An exposure apparatus is equipped with a fine movement stage that can hold a liquid with a projection optical system when the stage is at a position facing an outgoing surface of the projection optical system, and a blade that comes into proximity within a predetermined distance of the fine movement stage when the fine movement stage is holding the liquid with the projection optical system, and moves along with the fine movement stage while maintaining the proximity state, and then holds the liquid with the projection optical system after the movement. Accordingly, a plurality of stages will not have to be placed right under the projection optical system interchangeably, which can suppress an increase in footprint of the exposure apparatus.

Abstract: A substrate table of an immersion lithographic apparatus is disclosed which comprises a barrier configured to collect liquid. The barrier surrounds the substrate and is spaced apart from the substrate. In this way any liquid which is spilt from the liquid supply system can be collected to reduce the risk of contamination of delicate components of the lithographic projection apparatus.

Abstract: A fluid system to provide a fluid including liquid in a part of a lithographic apparatus, the fluid system including a manifold to mix a first liquid component and a second component to form the fluid in the part of the lithographic apparatus, a controller to control a physical property of the fluid by controlling the amount of the first and/or second component used to form the fluid, and a measuring device to measure a property of the fluid and to make feedback available to the controller, wherein the controller is configured to control the physical property of the fluid based on the measured property.

Abstract: In certain aspects, imaging optical systems with a plurality of mirrors image an object field in an object plane into an image field in an image plane. In the light path between non-obscured mirrors, imaging rays pass through at least one multiple pass-through region between spaced-apart planes which are arranged parallel to the object plane and/or parallel to the image plane. The imaging optical systems have at least one pupil plane. The pupil plane is arranged outside the multiple pass-through region between the non-obscured mirrors. This can provide an imaging optical system which provides for an easier correction of image errors.

Abstract: Embodiments of the invention related to lithographic apparatus and methods. A lithographic method comprises calculating a laser metric based on a spectrum of laser radiation emitted from a laser to a lithographic apparatus together with a representation of an aerial image of a pattern to be projected onto the substrate by the lithographic apparatus, and using the laser metric to modify operation of the laser or adjust the lithographic apparatus, and projecting the pattern onto the substrate.

Abstract: A substrate table of an immersion lithographic apparatus is disclosed which comprises a barrier configured to collect liquid. The barrier surrounds the substrate and is spaced apart from the substrate. In this way any liquid which is spilt from the liquid supply system can be collected to reduce the risk of contamination of delicate components of the lithographic projection apparatus.

Abstract: A stereoscopic image printing device includes an actuating unit for moving a grating structure, a print head for transferring a plurality of target image data onto corresponding positions of the grating structure, a first detecting module, a second detecting module, and a controller coupled to the print head, a first photosensitive component of the first detecting module, and a second photosensitive component of the second detecting module for controlling the print head to print some of the plurality of target image data onto the grating structure according to comparison between first optical intensity signal generated by the first detecting module and second optical intensity signal generated by the second detecting module.

Abstract: An optical module includes an aperture device and a support structure supporting the aperture device. The aperture device defines an aperture edge and an aperture plane. The aperture edge is adapted to define a geometry of a light beam passing the aperture device along an optical axis. The support structure is adapted to hold the aperture device in a defined manner when the aperture plane is inclined with respect to a horizontal plane. A temperature distribution prevails within the aperture device and at least one of the aperture device and the support structure is adapted to maintain at least one of a relative position of the aperture edge with respect to the optical axis and a geometry of the aperture edge substantially unaltered upon an introduction of a thermal energy into the aperture device, where the thermal energy being adapted to cause an alteration in the temperature distribution.

Abstract: The present invention provides an exposure apparatus comprising a projection optical system configured to project a pattern of a reticle onto a substrate, a driving unit configured to drive a plurality of optical elements which form the projection optical system so as to adjust an imaging state of light which passes through the projection optical system, a detecting unit configured to detect a driving error when the driving unit drives a first optical element of the plurality of optical elements, and a control unit configured to control the driving unit to drive a second optical element different from the first optical element of the plurality of optical elements so as to reduce a change in the imaging state of the light which passes through the projection optical system due to the driving error.

Abstract: Methods and control systems are provided for controlling stage position errors based, in some embodiments, on a selection of frequency components in a stage position error signal. An error frequency representation of a position error signal may be generated in the frequency domain and filtered by selecting one or more desired frequency components. The filtered error frequency representation can then be manipulated according to a control law and transformed back into the time domain to generate a current control signal. The current control signal can then be used to adjust the position of the stage to reduce positioning error.

Abstract: A device manufacturing apparatus includes a driving unit configured to perform driving for processing an object, a conduit through which a coolant that recovers heat generated by the driving unit flows, a cooler configure to cool the coolant that flows through the conduit, a heater configured to heat the coolant cooled by the cooler so that the driving unit cooled by the heated coolant has a target temperature, and a controller configured to heighten a target temperature of the coolant cooled by the cooler, if it is determined, based on control information to control the driving unit, that a heat amount to be generated by the driving unit decreases.

Abstract: A lithographic apparatus includes a projection system, a fluid handling structure, a metrology device, and a recycling control device. The projection system is configured to project a patterned radiation beam onto a target portion of a substrate, the substrate being supported on a substrate table. The fluid handling structure is configured to provide an immersion fluid to a space between the projection system and the substrate and/or substrate table. The metrology device is configured to monitor a parameter of the immersion fluid. The recycling control device regulates a routing of the immersion fluid either to be reused by the fluid handling structure or to be reconditioned based on the quality of immersion fluid indicated by the metrology device.

Abstract: A lithographic apparatus includes a projection system configured to project a patterned beam of radiation onto a substrate. The projection system being provided with an opening through which the patterned beam of radiation may pass. At least part of the opening comprises a sloped surface of a wall of the projection system and a sloped surface of a mirror of the projection system.