Avijit K. Ray-Chaudhuri scite author profile

Avijit K. Ray-Chaudhuri

5Publications

84Citation Statements Received

15Citation Statements Given

How they've been cited

136

How they cite others

Affiliations

Sandia National Laboratories, University of Wisconsin–Madison, Sandia National Laboratories California

Publications

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<title>Photoresist film thickness for extreme ultraviolet lithography</title>

Dentinger¹,

Cardinale²,

Henderson³

et al. 2000

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The thickness of the photoresist directly impacts the etch stand off and may impact the number of defects in the spin-coated film. However, the maximum imaging layer thickness for extreme ultraviolet lithography (EUVL) is limited by absorption of the radiation. Attenuation in photoresist materials at relevant EUV wavelengths was calculated with atomic extinction coefficients provided from Henke et aL The calculations indicated that photoresist materials have an optical density (O.D.) of 4.0 jtm1 (base e) so that 100 nm thick imaginlayers have approximately 67% transmission at 13.4 nm wavelength. Using Prolith/3D (Finle Technologies, Austin, TX) simulations of the effect of highly attenuating materials on sidewall slope were done and shown to be small.Imaging experiments were performed in a commercially-available DUV resist material on the lOxil microstepper and with an improved EUV'resist formulation. The imaging results agreed well with the calculations. Top down and cross-section images showed good sidewall profiles in 95nm thick films at the nominal dose because over 68% of the energy was transmitted through the film. When the thickness of the film was increased, the dose was increased slightly to compensate for the absorption while good sidewall profiles and linearity were maintained. Photoresist thicknesses as high as 145 nm were imaged with a 35% increase in dose. Results are also shown for a single layer resist exposed at 175 nm thickness with only slight sidewall degradation. It is shown that the imaging layer thickness for 13.4 nm lithography is likely to be 120 15 nm. If 1 1.4 nm wavelength radiation is chosen for EUV lithography, it is shown that thicknesses of 170 nm is possible.

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<title>System integration and performance of the EUV engineering test stand</title>

Tichenor¹,

Ray-Chaudhuri²,

Replogle³

et al. 2001

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The Engineering Test Stand (ETS) is a developmental lithography tool designed to demonstrate full-field EUV imaging and provide data for commercial-tool development. In the first phase of integration, currently in progress, the ETS is configured using a developmental projection system, while fabrication of an improved projection system proceeds in parallel. The optics in the second projection system have been fabricated to tighter specifications for improved resolution and reduced flare. The projection system is a 4-mirror, 4x-reduction, ring-field design having a numeral aperture of 0.1, which supports 70 nm resolution at a k 1 of 0.52. The illuminator produces 13.4 nm radiation from a laser-produced plasma, directs the radiation onto an arc-shaped field of view, and provides an effective fill factor at the pupil plane of 0.7. The ETS is designed for fullfield images in step-and-scan mode using vacuum-compatible, magnetically levitated, scanning stages. This paper describes system performance observed during the first phase of integration, including static resist images of 100 nm isolated and dense features.

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First lithographic results from the extreme ultraviolet Engineering Test Stand

Chapman

Ray-Chaudhuri

Tichenor

et al. 2001

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The extreme ultraviolet (EUV) Engineering Test Stand (ETS) is a step-and-scan lithography tool that operates at a wavelength of 13.4 nm. It has been developed to demonstrate full-field EUV imaging and acquire system learning for equipment manufacturers to develop commercial tools. The initial integration of the tool is being carried out using a developmental set of projection optics, while a second, higher-quality, projection optics is being assembled and characterized in a parallel effort. We present here the first lithographic results from the ETS, which include both static and scanned resist images of 100 nm dense and isolated features throughout the ring field of the projection optics. Accurate lithographic models have been developed and compared with the experimental results.

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Static microfield printing at the Advanced Light Source with the ETS Set-2 optic

Naulleau

Goldberg

Anderson

et al. 2002

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Method for compensation of extreme-ultraviolet multilayer defects

Ray-Chaudhuri

Cardinale

Fisher

et al. 1999

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