Abstract: Embodiments of the present disclosure relate to methods for fabricating optical devices. One embodiment of the method includes disposing a structure material layer on a surface of a substrate and disposing a patterned photoresist over the structure material layer. The patterned photoresist has at least one device portion and at least one auxiliary portion. Each device portion and each auxiliary portion exposes unmasked portions of the structure material layer. The unmasked portions of structure material layer corresponding to each device portion and each auxiliary portion are etched. The etching the unmasked portions forms at least one optical device having device structures corresponding to the unmasked portions of at least one device portion and at least one auxiliary region having auxiliary structures corresponding to the unmasked portions of at least one auxiliary portion.

Abstract: Embodiments of the present disclosure relate to methods for fabricating optical devices. One embodiment of the method includes disposing a structure material layer on a surface of a substrate and disposing a patterned photoresist over the structure material layer. The patterned photoresist has at least one device portion and at least one auxiliary portion. Each device portion and each auxiliary portion exposes unmasked portions of the structure material layer. The unmasked portions of structure material layer corresponding to each device portion and each auxiliary portion are etched. The etching the unmasked portions forms at least one optical device having device structures corresponding to the unmasked portions of at least one device portion and at least one auxiliary region having auxiliary structures corresponding to the unmasked portions of at least one auxiliary portion.

Abstract: A film structure for an electric field assisted bake process and methods of forming and implementing such a film structure are described herein. An example is a method for semiconductor processing. A photoresist is deposited on an underlayer disposed on a substrate. The underlayer includes carbon. The photoresist is exposed to a pattern of electromagnetic radiation. After exposing the photoresist, an electric field assisted bake is performed on the photoresist.

Abstract: Embodiments of the disclosure relate to lithography simulation and optical proximity correction. Field-guided post exposure bake processes have enabled improved lithography performance and various parameters of such processes are included in the optical proximity correction models generated in accordance with the embodiments described herein. An optical proximity correction model includes one or more parameters of anisotropic acid etching characteristics, ion generation and/or movement, electron movement, hole movement, and chemical reaction characteristics.

Abstract: Methods and apparatuses for minimizing line edge/width roughness in lines formed by photolithography are provided. A method of processing a substrate is provided. The method includes applying a photoresist layer that includes a photoacid generator to a multi-layer disposed on the substrate. The multi-layer includes an underlayer. Further, the method includes exposing a first portion of the photoresist layer unprotected by a photomask to a radiation light in a lithographic exposure process. A thermal energy is provided to the photoresist layer and the multi-layer in a post-exposure baking process. The multi-layer is disposed beneath the photoresist layer. An electric field or a magnetic field is applied to photoresist layer and the multi-layer while performing the post-exposure baking process. An additive within the underlayer is driven in a vertical direction into the photoresist layer. The additive assist in distribution of a photoacid throughout the photoresist layer during the post-exposure baking process.

Abstract: Embodiments of the present disclosure relate to methods for fabricating optical devices. One embodiment of the method includes disposing a structure material layer on a surface of a substrate and disposing a patterned photoresist over the structure material layer. The patterned photoresist has at least one device portion and at least one auxiliary portion. Each device portion and each auxiliary portion exposes unmasked portions of the structure material layer. The unmasked portions of structure material layer corresponding to each device portion and each auxiliary portion are etched. The etching the unmasked portions forms at least one optical device having device structures corresponding to the unmasked portions of at least one device portion and at least one auxiliary region having auxiliary structures corresponding to the unmasked portions of at least one auxiliary portion.

Abstract: Embodiments described herein relate to methods for fabricating optical devices. The methods described herein enable the fabrication of one or more optical devices on a substrate with apertures surrounding each of the optical devices having a plurality of structures. One embodiment of the methods described herein includes disposing an aperture material layer on a surface of a substrate, disposing a structure material layer over the apertures and the surface of the substrate, disposing a hardmask over the apertures and the structure material layer, disposing a patterned photoresist over the hardmask, the patterned photoresist defining exposed hardmask portions, removing the exposed hardmask portions to expose structure portions of the structure material layer, and removing the structure portions to form a plurality of structures between the apertures over regions of the surface of the substrate.