Radiation imagery chemistry: process – composition – or product th – Radiation modifying product or process of making – Radiation mask
Reexamination Certificate
1999-12-06
2001-11-20
Rosasco, S. (Department: 1756)
Radiation imagery chemistry: process, composition, or product th
Radiation modifying product or process of making
Radiation mask
C378S035000
Reexamination Certificate
active
06319635
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to minimizing defects in components produced by lithography, particularly to the mitigation of substrate defects in reticles or masks utilized in extreme ultraviolet lithography, and more particularly to the use of a multilayer buffer layer deposited intermediate a reticle substrate and a reflective coating for mitigating substrate defects in reticles.
2. Description of Related Art
Extreme ultraviolet lithography (EUVL) systems are being developed for the production of electronic components formed on wafers via reflected radiation. The EUVL systems include reticles or masks that must be essentially free of defects that will print at the wafer, thus producing defective components. The reticles, for example, may be fabricated by depositing highly reflective multilayer coatings, such as Mo/Si, on superpolished substrates. Any localized structural imperfections on the reticle substrate may nucleate and evolve during the multilayer coating process into a defect that perturbs the reflected radiation field sufficiently to print at the wafer. Thus, there has been a need for mitigating the effect of small particle contaminants on the surface of the substrate that would nucleate a defect in the reflective coating.
The reticle defect problem may be divided into two components. First, there are the defects associated with the condition of the reticle substrate. These are particles, pits, or scratches on the reticle substrate that nucleate a growth defect in the multilayer coating. Second, there are the defects that are introduced during or after the multilayer coating process, which are particle contaminants that are embedded within or are sitting on the top surface of the coating. A low defect multilayer coating technology based on ion beam sputtering has been developed so that the coatings now being deposited are essentially defect-free, thus the greater risk is the starting conditions of the reticle substrate.
Modeling has been carried out that shows imaging of growth defects nucleated by spherical particles. The results have indicated that particles as small as 25 nm in diameter will nucleate defects in multilayer coatings, which can image at the wafer. Hence, all particles of a size greater than 25 nm must be removed from the reticle substrates prior to the deposition of the reflective coating. Currently, removal of the particles from the reticle substrates is carried out by cleaning processes that are expected to be ineffective for the removal of particles of less than about 60 nm, particularly since verification that such small particles exist is difficult.
Prior efforts to resolve the reticle substrate defect problem involved a single layer buffer-layer, see K. B. Nguyen, et al.,
J. Vac. Sci. Technol.
11:2964 (1993), where a 200 nm thick single-layer amorphous silicon (a-Si) buffer-layer was deposited on the substrate prior to a Mo/Si multilayer deposition in an attempt to smooth out lithographically defined steps (defects) on a silicon surface. This resulted in some reduction in the defect height and the transition at the edges of the step was made less severe by the buffer-layer, which is advantageous. However, the surface roughness of the Si was increased significantly (from 0.2 nm to 0.7 nm), making this process impractical for EUV lithography.
Currently, there is a process having the capability of depositing a-Si approaching 200 nm in thickness with much lower roughness than that observed by Nguyen, referenced above. However, the large stress typically found in smooth, single-layer films like a-Si can limit the applicability of this single-layer approach for the buffer layer.
As an alternative to cleaning and single-layer buffer layers, the present invention mitigates the effects of these small particles by depositing a multilayer film as a buffer layer in between the substrate and the reflective coating. The purpose of this buffer layer is to reduce the perturbation of the reflective coating due to the particles, pits, or scratches on the substrate.
SUMMARY OF THE INVENTION
It is an object of the present invention to mitigate the effects of substrate defects in coated reticles used for extreme ultraviolet lithography. A further object of the invention is to provide a reticle substrate with a multilayer buffer layer to mitigate substrate defects. A further object of the invention is to provide a multilayer buffer layer between a reticle substrate and a multilayer reflective coating to mitigate the adverse effects of substrate defects. Another object of the invention is to provide a buffer layer between the substrate and a multilayer coating of a reticle utilized in extreme ultraviolet lithography.
Yet another object of the invention involves the mitigation of substrate defects in reticles for extreme ultraviolet lithography using multilayer buffer layers that are atomically smooth, have good smoothing properties, have low residual stress, and exhibit contraction during growth due to intermixing of the interfaces.
Other objects and advantages of the present invention will become apparent from the following description and accompanying drawings. The present invention is directed to mitigate the effects of particles or other defects on a reticle substrate, particularly having a size <60 nm, by depositing a multilayer film as a buffer layer between the substrate and the reflective coating. The purpose of this buffer layer is to reduce the perturbation of the reflective coatings due to the particles, pits, or scratches on the substrate. Specifically, the buffer layer is designed to smooth out the substrate topography to a point where the remaining perturbations are too small to nucleate printable growth defects in the reflective coating. The buffer multilayer is not used as a reflective coating, and thus its reflectivity to EUVL radiation need not be optimized.
The buffer layer exhibits several basic characteristics to be effective. The multilayer buffer layer provides smoothing behavior, that is, relaxation of the surface height variations due to the particles, pits and scratches on the substrate. The buffer layer also exhibits volume contraction during growth due to intermixing at the interfaces of the alternating layers. The buffer layer does not substantially increase the high spatial frequency roughness of the substrate surface (e.g., roughness is typically less than about 0.3 nm rms). The buffer layer has sufficiently low residual stress (less than about 500 MPa) so that a total buffer layer thickness of up to about 2 &mgr;m can be deposited without compromising the performance and stability of the reflective coating. Finally, the buffer layer deposition process must be clean; there must be no defects added in the process of growing the buffer multilayer.
The buffer layer may be made from materials different from the reflective coating, or from the same materials. Although the buffer layer may be made from the same materials as the reflective multilayer, the buffer layer serves a different function and is not optimized for high reflectance. The buffer layer differs structurally from the reflective coating because of the intermixing at the layer interfaces.
Multilayer materials that are atomically smooth, have good smoothing properties, have low residual stress, and exhibit contraction during growth due to intermixing at the interfaces may be used as the buffer layer. Multilayer systems that satisfy the above-listed buffer layer requirements include ion beam sputtered (IBS) molybdenum-silicon (Mo/Si) and MoRu/Be multilayer films. Other potential buffer layer multilayer materials that demonstrate the above-listed characteristics include Me/Si, Me/Be, Me/B, Me/B
4
C, and Me/C, where Me is a metal or alloy such as Mo, W, Ni, Cr, Ru, Rh, MoRu, or MoRh.
In the present invention, the multilayer buffer layer is deposited using an ultraclean ion beam sputtering process so that no defects are added in the deposition step. The multilayer buffer layer is deposited with minimal surface roughness and
Bajt Sasa
Mirkarimi Paul B.
Stearns Daniel G.
Carnahan L. E.
Rosasco S.
The Regents of the University of California
Thompson Alan H.
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