Abstract: An apparatus for use with extreme ultraviolet (EUV) light comprising A) a duct having a first end opening, a second end opening and an intermediate opening intermediate the first end opening the second end opening, B) an optical component disposed to receive EUV light from the second end opening or to send light through the second end opening, and C) a source of low pressure gas at a first pressure to flow through the duct, the gas having a high transmission of EUV light, fluidly coupled to the intermediate opening. In addition to or rather than gas flow the apparatus may have A) a low pressure gas with a heat control unit thermally coupled. to at least one of the duct and the optical component and/or B) a voltage device to generate voltage between a first portion and a second portion of the duet with a grounded insulative portion therebetween.

Abstract: An extreme ultraviolet (EUM) mask inspection system, comprising a light source to project EUV light along an optical axis, an illumination system to receive the EUV light from the source, the illumination system comprising a spectral purity filter (SPF), the SPF transmits a first portion of the EUV light along the optical axis toward a mask and the SPF comprising a plurality of at least partially reflective elements, said elements reflects a second portion of the EUV light off the optical axis, a projection system adapted to receive the first portion of the EUV light after it has illuminated the mask, a first detector array adapted to receive the image, and a second detector array to receive the second portion of the EUV light. The SPF may comprise one or more multilayer interference-type filters. Alternatively, the SPF comprises a thin film filter disposed on a grazing incidence mirror array.

Abstract: The present invention is a light homogenizer or light tunnel with highly reflective sides that enable the focusing of EUV illumination. The sides of the homogenizer are cut from a highly polished silicon wafer. The wafer is coated with a reflective coating before the strips are cut from the wafer. The invention also includes a method for flattening the strips and applying a backing to the strips enabling easier manipulation of the strips during assembly and use.

Abstract: A method and an apparatus to protect a reticle against particles and chemicals in an actinic EUV reticle inspection tool are presented. The method and apparatus utilizes a pair of porous metal diffusers in the form of showerheads to provide a continual flow of clean gas. The main showerhead bathes the reticle surface to be inspected in smoothly flowing, low pressure gas, isolating it from particles coming from surrounding volumes. The secondary showerhead faces away from the reticle and toward the EUV illumination and projection optics, supplying them with purge gas while at the same time creating a buffer zone that is kept free of any particle contamination originating from those optics.

Abstract: An apparatus for contaminant control, having: a first optical assembly including: a first light homogenizer tunnel with: a first end connected to an extreme ultra-violet light source, a second end in communication with a destination chamber, a first enclosed space, and, a first gas input arranged to introduce a first gas such that the first gas flows in a first direction toward the first end and in a second direction toward the second end. The apparatus alternately having: a second optical assembly including: a second light homogenizer tunnel with: a third end connected to an extreme ultra-violet light source, a fourth end in communication with a destination chamber, a second enclosed space, a diffusion barrier tube including: a fifth end facing the fourth end and a sixth end in communication with a destination chamber, and a second gas input between the second light homogenizer tunnel and the diffusion tube.

Abstract: The present disclosure is directed to an illumination system. The illumination system may include a base member rotatable about a rotation axis and a plurality of mirrors disposed on an outer surface of the base member along a perimeter of the base member. The mirrors may be oriented at a predetermined angle. The illumination system also includes at least two illumination sources. Each of the mirrors of the first plurality of mirrors is configured to receive radiation from the first illumination source at a first portion of each mirror at a first time. The mirror is configured to reflect the radiation to an optical path. Each of the mirrors is further configured to receive radiation from the second illumination source at a second portion of the mirror at a second time. The mirrors reflect the radiation from the second illumination source to the common optical path.

Abstract: An apparatus for actinic extreme ultra-violet (EUV) reticle inspection including at least one shape memory metal actuator adapted to displace an inspection component in an EUV inspection tool. An apparatus for actinic EUV reticle inspection including a tilt mechanism including at least one shape memory metal actuator adapted to angularly displace an inspection component in an EUV inspection tool. An apparatus for actinic EUV reticle inspection, including a translation stage adapted to fixedly connect to an inspection component, at least one flexure stage, and at least one shape memory metal actuator adapted to displace the translation stage.

Abstract: A method for reducing damage and contamination to an optical element in an extreme ultra-violet (EUV) reticle inspection system, including, presenting an illumination source to a reticle inspection system, and displacing the optical element in the path of the illumination source from a first portion to a second portion, wherein the first portion is damaged and the second portion is not damaged, and the optical element has a plurality of portions.

Abstract: An apparatus comprises an optics assembly and a plate. The optics assembly configured to focus light from an EUV source onto a reticle or sensor. The plate has an opening to allow the EUV light to pass through disposed between the optics assembly and the reticle or sensor. The plate is cooled to a temperature less than that of the reticle or sensor. The plate is engineered to balance out heat absorbed from the reticle or sensor with heat absorbed by the plate. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: Controlling particles near a reticle of a lithography or reticle inspection system may include generating a curtain of ultraviolet light about a reticle protection area of a reticle by illuminating a region surrounding the reticle protection area with ultraviolet light having sufficient energy to induce a charge on one or more particles traversing the curtain of ultraviolet light, generating an electric field in a region positioned between the generated curtain of ultraviolet light and the reticle protection area, the electric field generated between a first charging element and a second charging element having an opposite charge to the first charging element, directing one or more charged particles to the first charging element or the second charging element using the generated electric field; and capturing the one or more charged particles on the first charging element or the second charging element.

Abstract: A purging apparatus for a storage chamber is disclosed. The purging apparatus is configured for establishing a purge gas flow through the storage chamber. The purging apparatus may include a gas purifier and a particle filter. The gas purifier may provide a purge gas to the storage chamber. The purge gas may flow through the storage chamber, and a mixture of the purge gas and potential contaminants may subsequently exit the storage chamber as exhaust gas. The particle filter may receive and filter the exhaust gas. The filtered gas may be provided to the gas purifier for purification and recirculation. The gas purifier may purify the filtered gas by substantially removing at least one of: an acid, a base, an organic compound, water or oxygen from the filtered gas. The purified filtered gas may then be recirculated and provided to the storage chamber as the purge gas.

Abstract: An enclosure for a cavity enhanced optical spectroscopy instrument provides a highly temperature stable environment by positioning the instrument optical cavity away from the enclosure walls and providing a wall mounted heat pump, fan and heat exchanger. The fan causes the gas contained within the enclosure to circulate over the heat exchanger and in a laminar, non-turbulent flow path along interior wall surfaces of the enclosure thereby maintaining the optical cavity in a temperature and vibration stable zone.

Abstract: An enclosure for a cavity enhanced optical spectroscopy instrument provides a highly temperature stable environment by positioning the instrument optical cavity away from the enclosure walls and providing a wall mounted heat pump, fan and heat exchanger. The fan causes the gas contained within the enclosure to circulate over the heat exchanger and in a laminar, non-turbulent flow path along interior wall surfaces of the enclosure thereby maintaining the optical cavity in a temperature and vibration stable zone.