Techniques for controlling an optical system include accessing a measured value of a property of a particular pulse of a pulsed light beam emitted from the optical system, the property being related to an amount of coherence of the light beam; comparing the measured value of the property of the light beam to a target value of the property; determining whether to generate a control signal based on the comparison; and if a control signal is generated based on the comparison, adjusting the amount of coherence in the light beam by modifying an aspect of the optical system based on the control signal to reduce an amount of coherence of a pulse that is subsequent to the particular pulse.

An exposure apparatus transfers a pattern on a wafer by irradiating a reticle with an illumination light, and the pattern is formed on a pattern surface of the reticle. The exposure apparatus is provided with a reticle stage that moves holding the reticle, and a sensor that irradiates a measurement light on the pattern surface of the reticle held by the reticle stage and detects speckles from the pattern.

Techniques for controlling an optical system include accessing a measured value of a property of a particular pulse of a pulsed light beam emitted from the optical system, the property being related to an amount of coherence of the light beam; comparing the measured value of the property of the light beam to a target value of the property; determining whether to generate a control signal based on the comparison; and if a control signal is generated based on the comparison, adjusting the amount of coherence in the light beam by modifying an aspect of the optical system based on the control signal to reduce an amount of coherence of a pulse that is subsequent to the particular pulse.

Devices and methods for processing a radiation beam with coherence are disclosed. In one arrangement, an optical system receives a radiation beam with coherence. The radiation beam comprises components distributed over one or more radiation beam spatial modes. A waveguide supports a plurality of waveguide spatial modes. The optical system directs a plurality of the components of the radiation beam belonging to a common radiation beam spatial mode and having different frequencies onto the waveguide in such a way that each of the plurality of components couples to a different set of the waveguide spatial modes, each set comprising one or more of the waveguide spatial modes.

An image correction application relating to the ability to apply maskless lithography patterns to a substrate in a manufacturing process is disclosed. The embodiments described herein relate to a software application platform which maintains the ability to correct non-uniform image patterns using time-shifted exposures of the substrate. The application exposes subsequent portions of a substrate to electromagnetic radiation at variable and alternating pulse frequencies using a time delay in order to correct interference patterns and increase exposure uniformity.

A substrate handling apparatus for handling a substrate is disclosed. The substrate handling apparatus includes a substrate feeding device to feed the substrate towards an exposure area, a substrate receiving device to receive the substrate from the exposure area, and a substrate stabilization device to maintain, at least in the exposure area, the substrate substantially flat at an exposure height and/or tilt, the substrate stabilization device configured for contactless stabilization of the flexible substrate.

An illumination optical unit for EUV projection lithography guides illumination light to an illumination field, in which a lithography mask can be arranged. A facet mirror with a plurality of facets guides the illumination light to the illumination field. Respectively one illumination channel which guides an illumination light partial beam is predetermined by one of the facets. Exactly one illumination channel is guided over respectively one of the facets. The illumination optical unit is configured so that, at any time and at any point in the illumination field when the illumination optical unit is in operation, any pairs of illumination light partial beams guided over different illumination channels are incident on this illumination field point at times of incidence, the time difference of which is greater than a coherence duration of the illumination light.

An imaging assembly for directing a pattern of energy at a workpiece includes (i) a reticle that defines a reticle array that includes a plurality of spaced apart, transmitting regions; (ii) an illumination source that generates an illumination beam; and (iii) a director assembly that selectively directs the illumination beam at the reticle array, the director assembly includes a plurality of director elements that are individually controlled to selectively control the beam pattern that is directed at the reticle array.

An illumination unit for lithographic exposure and a device for lithographic exposure are disclosed. In an embodiment the illumination unit includes a beam source, an electronically drivable beam deflection element for generating a temporally varying two-dimensional beam deflection, a collimation lens, a beam homogenizing element, a Fourier lens and a field lens.

An image correction application relating to the ability to apply maskless lithography patterns to a substrate in a manufacturing process is disclosed. The embodiments described herein relate to a software application platform which maintains the ability to correct non-uniform image patterns using time-shifted exposures of the substrate. The application exposes subsequent portions of a substrate to electromagnetic radiation at variable and alternating pulse frequencies using a time delay in order to correct interference patterns and increase exposure uniformity.