Abstract: A self-referencing interferometer (SRI) system for an alignment sensor apparatus includes a first prism and a second prism. The first prism has an input surface for an incident beam. The second prism is coupled to the first prism and has an output surface for a recombined beam. The recombined beam includes a first image and a second image rotated by 180 degrees with respect to the first image. The first and second prisms are identical in shape. A dual self-referencing interferometer (DSRI) system for an alignment sensor apparatus includes a first prism assembly having an input surface for a first incident beam and a second incident beam, and a second prism assembly coupled to the first prism assembly and having an output surface for a first recombined beam and a second recombined beam. The first and second prism assemblies are identical in shape.

Abstract: An inspection system, a lithographic apparatus, and a method are provided. The inspection system includes an illumination system, an optical system, a shutter system, an objective system and a detector. The illumination system is configured to generate an illumination beam. The optical system is configured to split the illumination beam into a first sub-beam and a second sub-beam. The shutter system is configured to independently control a transmittance of the first sub-beam and the second subbeam. The objective system is configured to receive the first sub-beam and the second beam from the optical system and direct the first sub-beam and the second sub-beam towards a substrate having a target structure. The detector is configured to receive an image or a diffracted image of the target structure.

Abstract: An inspection apparatus includes a radiation source, an optical system, and a detector. The radiation source is configured to generate a beam of radiation. The optical system is configured to receive and direct the beam along an optical axis and toward a target so as to produce scattered radiation from the target. The optical system includes a beam displacer. The beam displacer includes two or more reflective surfaces. The beam displacer is configured to receive the beam along the optical axis, perform reflections of the beam so as to displace the optical axis of the beam, move linearly in at least a first dimension to shift the displaced optical axis, and preserve an optical property of the beam such that the optical property is invariant to the linear movement. The detector is configured to receive the scattered radiation and to generate a measurement signal based on the scattered radiation.

Abstract: An inspection apparatus includes a radiation source, an optical system, and a detector. The radiation source generates a beam of radiation. The optical system directs the beam along an optical axis and toward a target so as to produce scattered radiation from the target. The optical system includes a beam displacer including four reflective surfaces having a spatial arrangement. The beam displacer receives the beam along the optical axis, performs reflections of the beam so as to displace the optical axis of the beam, rotates to shift the displaced optical axis, and preserves polarization of the beam such that a polarization state of the beam along the deflected optical axis is invariant to the rotating based on the spatial arrangement of the four reflective surfaces. The detector receives the scattered radiation to generate a measurement signal based on the received scattered radiation.

Abstract: A metrology or inspection system, a lithographic apparatus, and a method are provided. The system includes an illumination system, an optical system, a first optical device, a second optical device, a detector, and a processor. The optical system is configured to split an illumination beam into a first sub-beam and a second sub-beam. The first optical device is configured to receive the first sub beam and direct the first sub-beam towards a first spot on a substrate. The substrate includes one or more target structures. The second optical device is configured to receive the second sub-beam and direct the second sub-beam towards a second spot on the substrate. The first spot is a different location than the second spot. The detector is configured to receive diffracted beams and to generate a detection signal. The processor is configured to determine a property of the one or more target structures.

Abstract: An inspection system, a lithographic apparatus, and a method are provided. The inspection system includes an illumination system, an optical system, a shutter system, an objective system and a detector. The illumination system is configured to generate an illumination beam. The optical system is configured to split the illumination beam into a first sub-beam and a second sub-beam. The shutter system is configured to independently control a transmittance of the first sub-beam and the second subbeam. The objective system is configured to receive the first sub-beam and the second beam from the optical system and direct the first sub-beam and the second sub-beam towards a substrate having a target structure. The detector is configured to receive an image or a diffracted image of the target structure.

Abstract: A self-referencing interferometer (SRI) system for an alignment sensor apparatus includes a first prism and a second prism. The first prism has an input surface for an incident beam. The second prism is coupled to the first prism and has an output surface for a recombined beam. The recombined beam includes a first image and a second image rotated by 180 degrees with respect to the first image. The first and second prisms are identical in shape. A dual self-referencing interferometer (DSRI) system for an alignment sensor apparatus includes a first prism assembly having an input surface for a first incident beam and a second incident beam, and a second prism assembly coupled to the first prism assembly and having an output surface for a first recombined beam and a second recombined beam. The first and second prism assemblies are identical in shape.

Abstract: According to one embodiment, a prism system is provided. The prism system includes a polarizing beam splitter (PBS) surface. The PBS surface is configured to generate first and second sub-beams having corresponding first and second polarization information from a received beam, the second polarization information being different than the first polarization information. A first optical path of the first sub-beam within the prism system has substantially same length as a second optical path of the second sub-beam within the prism system. Additionally or alternatively, the first sub-beam achieves a predetermined polarization extinction ratio.

Abstract: According to one embodiment, a prism system is provided. The prism system includes a polarizing beam splitter (PBS) surface. The PBS surface is configured to generate first and second sub-beams having corresponding first and second polarization information from a received beam, the second polarization information being different than the first polarization information. A first optical path of the first sub-beam within the prism system has substantially same length as a second optical path of the second sub-beam within the prism system. Additionally or alternatively, the first sub-beam achieves a predetermined polarization extinction ratio.

Abstract: According to one embodiment, a prism system is provided. The prism system includes a polarizing beam splitter (PBS) surface. The PBS surface is configured to generate first and second sub-beams having corresponding first and second polarization information from a received beam, the second polarization information being different than the first polarization information. A first optical path of the first sub-beam within the prism system has substantially same length as a second optical path of the second sub-beam within the prism system. Additionally or alternatively, the first sub-beam achieves a predetermined polarization extinction ratio.

Abstract: According to one embodiment, a prism system is provided. The prism system includes a polarizing beam splitter (PBS) surface. The PBS surface is configured to generate first and second sub-beams having corresponding first and second polarization information from a received beam, the second polarization information being different than the first polarization information. A first optical path of the first sub-beam within the prism system has substantially same length as a second optical path of the second sub-beam within the prism system. Additionally or alternatively, the first sub-beam achieves a predetermined polarization extinction ratio.