Ian Khaw scite author profile

Ian Khaw

4Publications

5Citation Statements Received

40Citation Statements Given

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University of South Florida

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Thin absorber extreme ultraviolet photomask based on Ni–TaN nanocomposite material

et al. 2016

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We study the use of random nanocomposite material as a photomask absorber layer for the next generation of extreme ultraviolet (EUV) lithography. By introducing nickel nanoparticles (NPs) randomly into a TaN host, the nanocomposite absorber layer can greatly reduce the reflectivity as compared with the standard TaN layer of the same thickness. Finite integral simulations show that the reduction in the reflectivity is mainly due to the enhanced absorption by the Ni NPs. The fluctuation in reflectivity induced by scattering and random position of the NPs is found to be on the order of 0.1%. Based on these observations, we build an effective medium model for the nanocomposite absorber layer and use the transfer matrix method to identify optimal absorber designs that utilize cavity effects to reduce the required volume fraction of Ni NPs. We further perform a process simulation and show that our approach can greatly reduce the HV bias in the lithography process.

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Ni-TaN Nanocomposite Absorber For Next-Generation Extreme Ultraviolet Lithography

Hay

Bagge

Khaw

et al. 2016

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Thin absorber EUV photomask based on mixed Ni and TaN material

Hay

Bagge

Khaw

et al. 2016

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Lithographic patterning at the 7 and 5 nm nodes will likely require EUV (λ=13.5 nm) lithography for many of the critical levels. All optical elements in an EUV scanner are reflective which requires the EUV photomask to be illuminated at an angle to its normal. Current scanners have an incidence of 6 degree, but future designs will be >6 degrees for high-NA systems. Non-telecentricity has been shown to cause H-V bias due to shadowing, pattern shift through focus, and image contrast lost due to apodization by the reflective mask coating. A thinner EUV absorber can dramatically reduce these issues. Ni offers better EUV absorption than Ta-based materials, which hold promise as a thinner absorber candidate. Unfortunately, the challenge of etching Ni has prevented its adoption into manufacturing. We propose a new absorber material that infuses Ni nanoparticles into the TaN host medium, allowing for the use of established Ta etching chemistry. A thinner is absorber is created due to the enhanced absorption properties of the Ni-Ta nano-composite material. Finite integral method and effective medium theory-based transfer matrix method have been independently developed to analyze the performance of the nano-composite absorption layer. We show that inserting 15% volume fraction Ni nanoparticles into 40-nm of TaN absorber material can reduce the reflection below 2% over the EUV range. Numerical simulations confirm that the reduced reflectivity is due to the increased absorption of Ni, while scattering only contributes to approximately 0.2% of the reduction in reflectivity.

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Reducing Blue Light Toxicity with Quantum‐Dot Technology

Harris¹,

Broyles²,

Garbar³

et al. 2023

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Ian Khaw

Thin absorber extreme ultraviolet photomask based on Ni–TaN nanocomposite material

Ni-TaN Nanocomposite Absorber For Next-Generation Extreme Ultraviolet Lithography

Thin absorber EUV photomask based on mixed Ni and TaN material

Reducing Blue Light Toxicity with Quantum‐Dot Technology

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