Abstract: A method of providing a pattern on a substrate is disclosed. The method includes providing a layer of photoresist on the substrate, providing a layer of top coating over the layer of photoresist, lithographically exposing the photoresist layer and developing the photoresist to form a structure, covering the structure with a coating layer, inducing a chemical reaction between the photoresist and the coating layer, which reaction does not occur in the top coating, to form regions of modified coating layer, and removing unmodified coating layer to leave behind a patterned structure formed from the regions of modified coating layer.

Abstract: An imprintable medium dispenser includes a chamber, a nozzle, and an actuator connected to the chamber and configured to be actuated and thereby generate a pressure wave within the chamber such that imprintable medium is dispensed from the nozzle. The imprintable medium dispenser is provided with a control circuit which includes a monitoring apparatus configured to receive a transient oscillation signal generated when the actuator is actuated, and to monitor the operation of the imprintable medium dispenser by monitoring the transient oscillation signal.

Abstract: Various types of pressure regulating devices are disclosed to reduce a pressure gradient in a liquid supply system of a lithographic apparatus, the liquid supply system having a liquid confinement structure configured to at least partially confine a liquid between a projection system and a substrate table of the lithographic apparatus. A high pressure gradient may cause particulate contamination in the liquid supply system and/or liquid confinement structure. A pressure gradient can be reduced by, for example, the use of slow switching in one or more valves, a bleed flow around or through one or more valves, diversion of liquid to a drain rather than or in addition to switching a valve off, a pressure regulator or flow restrictor to prevent shock waves, and a buffer volume/damper to compensate for pressure fluctuation.

Abstract: A foil trap is located in a path of a radiation beam. The foil trap includes an array of conductive strips. A voltage application circuit is coupled to the strips to apply voltage differences between pairs of adjacent ones of the strips. The voltage application circuit includes a current limiting circuit arranged to limit currents to the strips to values below a threshold value above which self-sustained arc discharge may arise in the foil trap.

Abstract: A lithographic apparatus has a plurality of different alignment arrangements that are used to perform an alignment measurement on the same mark(s) by: detecting a first alignment mark located on an object and producing a first alignment signal by a first detector; detecting the first mark and producing a second alignment signal by a second detector using a different alignment measurement than the first detector; receiving the first alignment signal from the first detector; calculating a first position of the at least first mark based on the first alignment signal; receiving the second alignment signal from the second detector; calculating a further first position of the at least first mark based on the second alignment signal.

Abstract: A lithographic apparatus includes a radiation system configured to form a projection beam of radiation. The radiation system includes a radiation source that emits radiation, a filter system for filtering debris particles out of the radiation beam, and an illumination system configured to condition a radiation beam. A projection system is configured to project the projection beam of radiation onto a substrate. The filter system includes a plurality of foils for trapping the debris particles. At least one foil includes at least two parts that have a mutually different orientation and that are connected to each other along a substantially straight connection line. Each of the two parts substantially coincide with a virtual plane that extends through a predetermined position that substantially coincides with the radiation source. The straight connection substantially line coincides with a virtual straight line that also extends through the predetermined position.

Abstract: Methods, computer program products and apparatuses for optimizing design rules for producing a mask are disclosed, while keeping the optical conditions (including but not limited to illumination shape, projection optics numerical aperture (NA) etc.) fixed. A cross-correlation function is created by multiplying the diffraction order functions of the mask patterns with the eigenfunctions from singular value decomposition (SVD) of a TCC matrix. The diffraction order functions are calculated for the original design rule set, i.e., using the unperturbed condition. ILS is calculated at an edge of a calculated image of a critical polygon using the cross-correlation results and using translation properties of a Fourier transform. The use of the calculated cross-correlation of the mask and the optical system, and the translation property of the Fourier transform for perturbing the design reduces the computation time needed for determining required changes in the design rules.

Abstract: A liquid handling structure for a lithographic apparatus comprises a droplet controller configured to allow a droplet of immersion liquid to be lost from the structure and to prevent the droplet from colliding with the meniscus of the confined immersion liquid. The droplet controller may comprise gas knives arranged to overlap to block an incoming droplet. There may be extraction holes lined up with gaps between gas knives to extract liquid that passes through the gap. A droplet is allowed to escape through the gaps.

Abstract: Improved convergence in the volume-integral method (VIM) of calculating electromagnetic scattering properties of a structure is achieved by numerically solving a volume integral equation for a vector field, F, rather than the electric field, E. The vector field, F, may be related to the electric field, E, by a change of basis, and may be continuous at material boundaries where the electric field, E, has discontinuities. Convolutions of the vector field, F, are performed using convolution operators according the finite Laurent rule (that operate according to a finite discrete convolution), which allow for efficient matrix-vector products via 1D and/or 2D FFTs (Fast Fourier Transforms). An invertible convolution-and-change-of-basis operator, C, is configured to transform the vector field, F, to the electric field, E, by performing a change of basis according to material and geometric properties of the periodic structure.

Abstract: A method controls a scanning function of a lithographic apparatus. A first alignment strategy is used. A monitor wafer is exposed to determine baseline control parameters pertaining to the scanning function. The baseline control parameters are periodically retrieved from the monitor wafer. Parameter drift is determined from the baseline control parameters. Corrective action is taken based on the determination. A production wafer is exposed using a second alignment strategy, different to the first alignment strategy. The corrective action is modified so as to be substantially closer to the correction that would have been made had the second alignment strategy been used in exposing the monitor wafer.

Abstract: A lithographic apparatus includes an illumination system configured to provide a first beam of radiation, which forms a first mask illumination region, and configured to substantially simultaneously provide a second beam of radiation, which forms a second mask illumination region. The first and second illumination regions being configured to substantially simultaneously illuminate a same mask. The lithographic apparatus also includes a projection system configured to project the first radiation beam such that it forms a first substrate illumination region and configured to simultaneously project the second radiation beam such that it forms a second substrate illumination region.

Abstract: A lithographic apparatus includes a first support to support a first patterning device; a second support to support a second patterning device, each of the first and the second patterning device capable of imparting a radiation beam with a pattern in its cross-section to form a patterned radiation beam; a substrate table constructed to hold a substrate; a projection system to project the patterned radiation beam onto a target portion of the substrate; a controller to drive the first support and the second support and arranged to: drive the first support to perform a scanning movement; drive the second support to accelerate during at least part of the scanning movement of the first support; and drive the second support to perform a scanning movement upon completion of the scanning movement of the first support, so as to scan a die adjacent a die previously scanned during the scanning movement of the first support.

Abstract: A lithographic apparatus includes a support configured to hold an object, the support being moveable relative to a reference structure in a direction; a first position measurement system configured to provide a first measurement signal in a first frequency range, the first measurement signal representative of a position of the support relative to the reference structure in the direction; a second position measurement system configured to provide a second measurement signal in a second frequency range, the second measurement signal representative of the position of the support relative to the reference structure in the direction; and a processor configured to (a) filter the first measurement signal so as to attenuate a signal component having a frequency in the second frequency range, (b) filter the second measurement signal so as to attenuate a signal component having a frequency in the first frequency range, and (c) combine the filtered first measurement signal and the filtered second measurement signal into

Abstract: A lithographic apparatus operates by moving a substrate and a patterning device relative to each other in a sequence of movements such that a pattern is applied at a successive portions on the substrate. Each portion of the substrate is patterned by a scanning operation in which the patterning device is scanned through the radiation beam while synchronously scanning the substrate through the patterned radiation beam so as to apply the pattern to the desired portion on the substrate. An intrafield correction is applied during each scanning operation so as to compensate for distortion effects which vary during the scanning operation. The intrafield correction includes corrective variations of one or more properties of the projection system, and optionally out-of-plane movements of the patterning device and/or substrate table.

Abstract: A radiation sensor includes a radiation receiver positioned in a focal plane of the final element of the projection system; a transmissive plate supporting the radiation receiver at a side facing the projection system; a quantum conversion layer to absorb light at the first wavelength incident on the transmissive plate and reradiate light at a second wavelength; a fiber optics block with a plurality of optical fibers; and a radiation detector. In the radiation sensor, the plurality of optical fibers guide light is reradiated by the quantum conversion layer towards the radiation detector. The radiation sensor can be used as a substrate-level sensor in a lithographic apparatus.

Abstract: In an immersion lithographic apparatus, a final element is disclosed having, on a surface nearest the substrate, a layer bonded to the surface and having an edge barrier, of the same material as the layer, extending from the layer away from the substrate to shield the final element from a liquid. In an embodiment, the final element is attached to the apparatus via the layer and/or edge barrier, which may be made of a material with a coefficient of thermal expansion lower than the coefficient of thermal expansion of the final element.

Abstract: A lithographic apparatus is disclosed that has a first substrate table arranged to hold a substrate and a second substrate table arranged to hold a substrate, an imprint template holder arranged to hold an imprint template, and an imprintable medium dispenser, wherein the first substrate table is moveable between a first position located at or adjacent to the imprintable medium dispenser, and a second position located at or adjacent to the imprint template holder, and the second substrate table is moveable between the first and second positions, such that the first and second substrate tables swap positions.

Abstract: A cleaning tool to clean a surface of a component of a lithographic apparatus is disclosed. The cleaning tool includes a sonic transducer, a liquid supply device configured to provide liquid to a reservoir between the surface to be cleaned and the sonic transducer, and a liquid outlet configured to remove liquid provided by the liquid supply device, the cleaning tool constructed and arranged such that, in use, liquid flows into the outlet under the influence of gravity.

Abstract: In a lithographic apparatus, a feedforward transfer function of a control system is determined by: a) iteratively learning a feedforward output signal of the control system by iterative learning control for a given setpoint signal; b) determining a relation between the learned feedforward output signal and the setpoint signal; and c) applying the relation as the feedforward transfer function of the control system. A learned feedforward, which has been learned for one or more specific setpoint signals only, can be adapted to provide a setpoint signal dependent feedforward output signal. The learned feedforward can be made more robust against setpoint variations.

Abstract: A lithographic apparatus includes a movable table constructed and arranged to transport an object to a position in a beam path in a vacuum chamber, a first capacitor electrode and a second capacitor electrode attached to the table, a first inductor assembly coupled to the capacitor electrodes, and configured to apply a voltage between the first capacitor electrode and the second capacitor electrode, and a second inductor assembly mounted at a position that remains fixed when the table is moved. The second inductor assembly is configured to generate a magnetic field. The presence of the object on the table is detected by applying a voltage on the second inductor assembly which will result in a magnetic field which when picked up by the first inductor assembly will create a magnetic field response in the first inductor assembly dependent on the capacitance of the capacitor electrodes.