Neutron Reflectivity Characterization of the Photoacid Reaction-Diffusion Latent and Developed Images of Molecular Resists for Extreme Ultraviolet Lithography

Prabhu, Vivek M.; Kang, Shuhui; Sha, Jing; Bonnesen, Peter V.; Satija, Sushil K.; Wu, Wen‐Li; Ober, Christopher K.

doi:10.1021/la301311m

Cited by 11 publications

(7 citation statements)

References 73 publications

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“…A few studies have been able to measure acid diffusivity using semidirect methods. One approach detected the time required for the acid to diffuse through a polymer film of known thickness, and then used Fick’s second law to estimate the diffusivity. , Another approach employed neutron reflectivity to record the shape of the reaction front, − and then extracted the diffusivity using a model of Fickian acid transport coupled to fast deprotection and acid trapping. However, indirect methods to examine acid diffusion and acid loss are more prevalent in the literature.…”

Section: Introductionmentioning

confidence: 99%

Ion Diffusion in Chemically Amplified Resists

et al. 2021

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The acid-catalyzed deprotection of glassy polymer resins is an important process in semiconductor lithography. Studies have shown that the reaction kinetics in these materials is controlled by slow diffusion of the acid−anion catalyst, but trends deviate from models of a first-order reaction coupled to a composition-invariant Fickian diffusivity. We present a concerted experimental and computational effort to examine catalyst diffusion in a model resin of poly(4-hydroxystyrene-co-tert-butyl acrylate-co-styrene), or P-(HOSt-tBA-St), which is deprotected in the presence of an acid catalyst to poly(4-hydroxystyrene-co-acrylic acid-co-styrene), or P(HOSt-AA-St). We employed an inert catalyst analogue to examine long-time ion dynamics in both terpolymers with atomistic molecular dynamics simulations and compared the calculated Fickian diffusivities with direct measurements of ion diffusion fronts using time-of-flight secondary ion mass spectrometry. Our results demonstrate that ion diffusivities in P(HOSt-tBA-St) and in P(HOSt-AA-St) are similar near and below the glass transition, consistent with a diffusion process that is dominated by interactions with the polar HOSt units. We then compared the bulk reaction kinetics measured by Fourier-transform infrared spectroscopy with reaction kinetics obtained using mesoscopic reaction−diffusion models. We found that initial reaction kinetics is significantly accelerated compared to predictions based on the long-time ion diffusivities of our inert system. This study highlights the potential of atomistic modeling coupled with targeted experiments for interrogating the physical and chemical processes that control pattern formation in next-generation lithographic materials.

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Section: Introductionmentioning

confidence: 99%

Ion Diffusion in Chemically Amplified Resists

et al. 2021

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“…We further optimized the lithographic performance of the thiol–ene resist systems under a variety of conditions including reduced exposure doses, adjusted the monomer concentrations and ratios of alkenes to thiols, and selected the carboxyl ligand developers (e.g., acetic acid/acetone mixture) (Figure S16). The photoelectron/radical diffusion process, in contrast to photoacid diffusion, makes non-negligible contributions to the residue of unexposed areas or bridges, especially for highly sensitive free radical-type systems. ,− The deep-UV exposure results (Figure e) indicated that the residual issue was significantly improved by the addition of adequate hydroquinone (2 wt % to monomers, with all other conditions identical). After being exposed to a dose of 10 mJ cm –2 and developed in toluene for 30 s, clear 1:1 L/S dense patterns were observed.…”

Section: Resultsmentioning

confidence: 99%

Exceptional Light Sensitivity by Thiol–Ene Click Lithography

et al. 2023

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Lithographic patterning, which utilizes the solubility switch of photoresists to convert optical signals into nanostructures on the substrate, is the primary top-down approach for nanoscale fabrication. However, the low light/electron-energy conversion efficiency severely limits the throughput of lithography. Thiol–ene reaction, as a photoinitiated radical addition reaction, is widely known as click reaction in the field of chemistry due to its extremely high efficiency. Here, we introduce a click lithography strategy utilizing the rapid thiol–ene click reaction to realize ultraefficient nanofabrication. This novel approach facilitated by the implementation of ultrahigh-functionality material designs enables high-contrast patterning of metal-containing nanoclusters under an extremely low deep-ultraviolet exposure dose, e.g., 7.5 mJ cm–2, which is 10–20 times lower than the dose used in the photoacid generator-based photoresist system. Meanwhile, 45 nm dense patterns were also achieved at a low dose using electron beam lithography, revealing the great potential of this approach in high-resolution patterning. Our results demonstrated the high-sensitivity and high-resolution features of click lithography, providing inspiration for future lithography design.

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“…Poly(4‐hydroxystyrene)s (PHOSTs) are widely used in many fields such as drug therapy agents, 1 drug delivery, 2 self‐healing materials 3,4 and photoresists 5‐7 . When PHOSTs are used as photoresists resin for KrF and EUV photolithography process, 6,7 the pattern resolution is largely limited by molecular weight distribution (MWD), 8‐11 with critical dimension of the device features extends below 22 nm. Living or quasiliving cationic polymerization (LCP or QLCP) has offered a strategy for the macromolecular design with alkyl vinyl ethers, 12 isobutene, 13 styrene and its derivatives 14‐19 .…”

Section: Introductionmentioning

confidence: 99%

Synthesis of benzyl chlorine‐free poly(4‐acetoxystyrene) via cationic polymerization followed by Friedel‐Crafts alkylation

Wen

Liu

Liang

2021

Polymers for Advanced Techs

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The linear benzyl chlorine‐free poly(4‐acetoxystyrene) (PSTO) with low polydispersity (Mw/Mn = 1.3) is obtained through anisole quenching of the living polymerization of 4‐acetoxystyrene initiated with the St–Cl/SnCl4/n‐Bu4NBr system in CH2Cl2. The alkylation reaction rate increases with increasing anisole concentration and temperature. With a 4‐fold excess of anisole over the initiator, end‐chlorine groups are completely capped by anisole in 30 minutes at −15°C through adding extra SnCl4 prior to the alkylation reaction. In addition, by using 2‐methylanisole and 2,6‐dimethylanisole as capping agents, it is verified that both para‐ and ortho‐positions substitution of living PSTO cations to the anisole occur during alkylation reactions.

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Neutron Reflectivity Characterization of the Photoacid Reaction-Diffusion Latent and Developed Images of Molecular Resists for Extreme Ultraviolet Lithography

Cited by 11 publications

References 73 publications

Ion Diffusion in Chemically Amplified Resists

Ion Diffusion in Chemically Amplified Resists

Exceptional Light Sensitivity by Thiol–Ene Click Lithography

Synthesis of benzyl chlorine‐free poly(4‐acetoxystyrene) via cationic polymerization followed by Friedel‐Crafts alkylation

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