A pellicle having a metal oxysilicide layer. A pellicle having a molybdenum layer, a ruthenium layer and a silicon oxynitride layer, wherein the molybdenum layer is disposed between the ruthenium layer and the silicon oxynitride layer. A method of manufacturing a pellicle for a lithographic apparatus, the method including providing a metal oxysilicide layer. A lithographic assembly including a pellicle having a metal oxysilicide layer. The use of a pellicle having a metal oxysilicide layer in a lithographic apparatus.

A method for operating an optical apparatus (100A, 100B, 200), having a structural element (201) which is arranged in a residual gas atmosphere (RGA) of the apparatus and which is formed at least partly from an element material subjected to a chemical reduction process and/or an etching process with a plasma component (PK) present in the residual gas atmosphere includes: feeding (S2) a gas component (GK) that at least partly suppresses the reduction process depending on a detected suppression extent (UM) for a suppression of the etching process and/or reduction process by the suppressing gas component in the residual gas atmosphere; and detecting (S1) the suppression extent with a sensor unit (208) arranged in the residual gas atmosphere. The sensor unit includes a sensor material section (211) composed of a sensor material and exhibiting a sensor section property that is measurable under the influence of the suppressing gas component.

Membranes for EUV lithography are disclosed. In one arrangement, a membrane has a stack having layers in the following order: a first capping layer including an oxide of a first metal; a base layer including a compound having a second metal and an additional element selected from the group consisting of Si, B, C and N; and a second capping layer including an oxide of a third metal, wherein the first metal is different from the second metal and the third metal is the same as or different from the first metal.

A pellicle for an EUV photo mask includes a base membrane layer, a core layer disposed over the base membrane layer and one or more metallic layers disposed over the core layer.

A pellicle and a method for manufacturing a pellicle that can improve the production yield ratio are provided. A method for manufacturing a pellicle comprises a step to prepare a supporting member containing Si, and a step to form a pellicle film on a top surface of the supporting member. The step to form the pellicle film includes: a step to form a SiC film with a first average carbon concentration on the top surface of the supporting member by carbonizing Si, and a step to form a SiC film with a second average carbon concentration different from the first average carbon concentration on the top surface of the SiC film. The method for manufacturing a pellicle further comprises a step to exposes at least a part of the reverse side of the SiC film by wet etching.

A pellicle removal tool including a stage that holds a photomask and an associated pellicle, two or more arms positioned around the stage and configured to engage pellicle side wells of the pellicle, and two or more actuators each configured to adjust at least a vertical position of a corresponding one of the two or more arms so as to apply a lifting force to the pellicle for removal of the pellicle from the photomask.

The present disclosure relates to a lithography scanner including: a light source configured to emit extreme ultra-violet (EUV) light; a pellicle including an EUV transmissive membrane that is configured to scatter the EUV light into an elliptical scattering pattern having a first major axis; a reticle configured to reflect the scattered EUV light through the pellicle; and an imaging system configured to project a portion of the reflected light that enters an acceptance cone of the imaging system onto a target wafer, wherein a cross section of the acceptance cone has a second major axis, and wherein the pellicle is arranged such that the first major axis is oriented at an angle relative to the second major axis.

The present disclosure provides a mask for photolithography patterning. The mask includes a substrate, a pattern layer on a surface of the substrate. The mask also includes a pellicle attached to the substrate and configured to isolate the pattern layer from ambient. The pellicle includes a membrane between the pattern layer and ambient, a frame for securing the membrane on the substrate, and an optical member disposed in the membrane. A method for manufacturing the mask is also provided.

A lithography patterning system includes a reticle having patterned features, a pellicle having a plurality of openings, a radiation source configured for emitting radiation to reflect and/or project the patterned features, and one or more mirrors configured for guiding reflected and/or projected patterned features onto a wafer. The pellicle is configured to protect the reticle against particles and floating contaminants. The plurality of openings include between 5% and 99.9% of lateral surface area of the pellicle. The pellicle can be attached to the reticle on a side of the patterned features, placed beside an optical path between the radiation source and the wafer, or placed in an optical path between mirrors and the radiation source. The plurality of openings in the pellicle are formed by a plurality of bar shaped materials, or formed in a honey comb structure or a mesh structure.

Embodiments described herein relate to a dynamically controlled lens used in lithography tools. Multiple regions of the dynamic lens can be used to transmit a radiation beam for lithography process. By allowing multiple regions to transmit the radiation beam, the dynamically controlled lens can have an extended life cycle compared to conventional fixed lens. The dynamically controlled lens can be replaced or exchanged at a lower frequency, thus, improving efficiency of the lithography tools and reducing production cost.