Abstract: A tunable dielectric antireflective layer for use in photolithographic applications, and specifically, for use in an image transfer processing. The tunable dielectric antireflective layer provides a spin-on-glass (SOG) material that can act as both a hardmask and a deep UV antireflective layer (BARC). One such material is titanium oxide generated by spin-coating a titanium alkanate and curing the film by heat or electron beam. The material can be “tuned” to match index of refraction (n) with the index of refraction for the photoresist and also maintain a high absorbency value, k, at a specified wavelength. A unique character of the tunable dielectric antireflective layer is that the BARC/hardmask layer allows image transfer with deep ultraviolet photoresist.

Abstract: A topcoat material for applying on top of a photoresist material is disclosed. The topcoat material comprises at least one solvent and a polymer which has a dissolution rate of at least 3000 ?/second in aqueous alkaline developer. The polymer contains a hexafluoroalcohol monomer unit comprising one of the following two structures: wherein n is an integer. The topcoat material may be used in lithography processes, wherein the topcoat material is applied on a photoresist layer. The topcoat material is preferably insoluble in water, and is therefore particularly useful in immersion lithography techniques using water as the imaging medium.

Abstract: A method of forming a top coat layer and a topcoat material for use in immersion lithography. A topcoat layer is formed on a photoresist layer from an aqueous solution that is immiscible with the photoresist layer. The topcoat layer is then rendered insoluble in neutral water but remains soluble in aqueous-base developer solutions so the photoresist may be exposed in a immersion lithographic system using water as the immersion fluid, but is removed during photoresist development. The topcoat materials are suitable for use with positive, negative, dual tone and chemically amplified (CA) photoresist.

Abstract: A method of forming a top coat layer and a topcoat material for use in immersion lithography. A topcoat layer is formed on a photoresist layer from an aqueous solution that is immiscible with the photoresist layer. The topcoat layer is then rendered insoluble in neutral water but remains soluble in aqueous-base developer solutions so the photoresist may be exposed in a immersion lithographic system using water as the immersion fluid, but is removed during photoresist development. The topcoat materials are suitable for use with positive, negative, dual tone and chemically amplified (CA) photoresist.

Abstract: A topcoat material for applying on top of a photoresist material is disclosed. The topcoat material comprises at least one solvent and a polymer which has a dissolution rate of at least 3000 ?/second in aqueous alkaline developer. The polymer contains a hexafluoroalcohol monomer unit comprising one of the following two structures: wherein n is an integer. The topcoat material may be used in lithography processes, wherein the topcoat material is applied on a photoresist layer. The topcoat material is preferably insoluble in water, and is therefore particularly useful in immersion lithography techniques using water as the imaging medium.

Abstract: An optical apparatus used for the efficient characterization of photoresist material includes at least one grating interferometer having at least two gratings that together define an optical recombination plane. An optical stop blocks any zeroth order beam from propagating through the apparatus. A reticle positioned at the recombination plane has at least one fiducial marking therein. A lithographic imaging optical tool is positioned so that its input optical plane is substantially coincident with the optical recombination plane and its output imaging plane is substantially coincident with photoresist on a wafer. The apparatus writes in the photoresist latent, sinusoidal grating patterns, preferably of different spatial frequencies, as well as at least one fiducial mark whose pattern is determined by the marking in the reticle. After the photoresist is developed, its intrinsic spatial resolution may be determined by automated means.

Abstract: An efficient method and system is provided for computing lithographic images that takes into account vector effects such as lens birefringence, resist stack effects and tailored source polarizations, and may also include blur effects of the mask and the resist. These effects are included by forming a generalized bilinear kernel, which is independent of the mask transmission function, which can then be treated using a decomposition to allow rapid computation of an image that includes such non-scalar effects. Dominant eigenfunctions of the generalized bilinear kernel can be used to pre-compute convolutions with possible polygon sectors. A mask transmission function can then be decomposed into polygon sectors, and weighted pre-images may be formed from a coherent sum of the pre-computed convolutions for the appropriate mask polygon sectors. The image at a point may be formed from the incoherent sum of the weighted pre-images over all of the dominant eigenfunctions of the generalized bilinear kernel.

Abstract: An optical apparatus used for the efficient characterization of photoresist material includes at least one grating interferometer having at least two gratings that together define an optical recombination plane. An optical stop blocks any zeroth order beam from propagating through the apparatus. A reticle positioned at the recombination plane has at least one fiducial marking therein. A lithographic imaging optical tool is positioned so that its input optical plane is substantially coincident with the optical recombination plane and its output imaging plane is substantially coincident with photoresist on a wafer. The apparatus writes in the photoresist latent, sinusoidal grating patterns, preferably of different spatial frequencies, as well as at least one fiducial mark whose pattern is determined by the marking in the reticle. After the photoresist is developed, its intrinsic spatial resolution may be determined by automated means.