Acid Generation Efficiency of EUV PAGs via Low Energy Electron Exposure

Grzeskowiak, Steven; Narasimhan, Amrit; Rebeyev, Eliran; Joshi, Shresht; Brainard, Robert L.; Denbeaux, Greg

doi:10.2494/photopolymer.29.453

Cited by 22 publications

(17 citation statements)

References 18 publications

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“…For reactions in EUV resists (or other systems) where there is a volatile byproduct, mass spectrometry can be used for quantitative measurement of reactions (Sec. 3) [29][30][31][32] . For the three metal-oxalate complexes, the proposed photomechanism suggests the first step in the photochemical process is the oxidation of the oxalate ligand with the accompanied reduction of the metal from M(III) to M(II) ultimately leading to a change in solubility when the coordination complex is formed 10 .…”

Section: Discussionmentioning

confidence: 99%

“…The oxalate ligand will decompose readily when detached from the metal center and produce carbon dioxide in the process. The rate of CO2 production can be monitored using in situ mass spectrometry measurements [29][30][31][32] . [24][25][26][27][28] .…”

Section: Cr2+mentioning

confidence: 99%

“…Consequently, an 80 eV electron exposure is used as a model for EUV exposure mechanisms. Electron outgassing experiments are completed in our electron-resist interaction chamber (ERIC) [29][30][31][32] .…”

Section: Electron Reactivitymentioning

confidence: 99%

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Reactivity of metal-oxalate EUV resists as a function of the central metal

et al. 2017

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Extreme Ultraviolet light (EUV, ~13.5 nm) is the likely subsequent technology for high volume manufacturing for the microelectronics industry. Traditional EUV photoresists have been composed of organic compounds which are moderately transparent to EUV. Resist stochastics and sensitivity can be improved by increasing the number of photons absorbed. Molecular organometallic resists are a type of metal containing resist aimed at improving EUV absorption. This work focuses on studying the role of the metal center (Metal = Co, Fe, Cr) in an oxalate complex by comparing the number of absorbed photons and the photoelectron reactivity in each compound.In the study presented here, the EUV absorption coefficients are determined experimentally by measuring the transmission through a resist coated on a silicon nitride membrane using an Energetiq EQ-10M xenon plasma EUV source. Additionally, the photochemistry is evaluated by monitoring outgassing reaction products. This particular resist platform eliminates oxalate ligands when exposed to electrons or EUV photons resulting in a solubility difference between the exposed and unexposed regions. In the process, carbon dioxide is produced and is monitored using mass spectrometry, where quantitative values are obtained using a calibration technique.For the metal oxalate complexes studied, the absorption of EUV changed minimally due to the low concentrations of metal atoms. However, EUV and electron reactivity greatly changed between the three compounds likely due to the reducibility of the metal center. A correlation is shown between Esize and the reducibility of each photoresist.

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Section: Discussionmentioning

confidence: 99%

Section: Cr2+mentioning

confidence: 99%

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Reactivity of metal-oxalate EUV resists as a function of the central metal

et al. 2017

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“…Our recent work has focused on investigating the photomechanism of our antimony-carboxylate platform, by studying the volatile photoproducts following exposure to EUV (Fig. 1) [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Isotopic Labeling Studies of EUV Photoresists Containing Antimony

Murphy

Sitterly

Grzeskowiak

et al. 2018

J. Photopol. Sci. Technol.

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We have investigated the mechanism of photodecomposition of antimony carboxylate complexes of the type Ph 3 Sb(O 2 CR′) 2 by means of EUV outgassing in combination with isotopic labeling. When exposed to EUV light, these compounds decompose to form CO 2 , benzene and phenol. The source of hydrogen needed to create phenol can be traced to hydrogens originating in the original organometallic complex. However, it is much more difficult to trace the origin of the hydrogen needed to convert the phenyl groups to benzene (Ph-H). We propose that the primary source of hydrogen to create benzene is external to the film. Additionally, we have prepared isotopically-labeled versions of Ph3Sb(O2CCH(CH3)2)2 in which the hydrogens in the isobutyrate ligand were replaced with 0, 1, 6 and 7 deuteriums, to provide information about the relative reactivity of these protons during EUV exposure as analyzed by mass spectrometry. High reaction selectivity was identified within the carboxylate dictated by hydrogen location relative to the carbonyl for both benzene and phenol generation. Lastly, the results of these studies were used to propose a series of reaction pathways to generate the aforementioned reaction byproducts.

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“…To better understand the chemistry occurring during exposure, we identified outgassed reaction products generated during photolysis via mass spectrometry [13][14][15]. In our initial experiment, we exposed a film of JP-18 to EUV and collected the positive-ion mass spectral data (Fig.…”

Section: Reaction Product Identificationmentioning

confidence: 99%

EUV Mechanistic Studies of Antimony Resists

Murphy

Narasimhan

Grzeskowiak

et al. 2017

J. Photopol. Sci. Technol.

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We have developed a method to study the photomechanism of our antimony carboxylate platform Ph 3 Sb(O 2 CR') 2 . A series of mechanistic studies followed the production of reaction byproducts by mass spectrometer, as they leave the film during exposure to EUV photons or 80 eV electrons. The major volatile products are CO 2 , benzene and phenol. The rate of outgassing is well-correlated with the reaction energy of decarboxylation of the carboxylate ligand as determined by density functional theory. Additionally, a deuterium labeling study was conducted to determine the source of hydrogen needed to convert phenyl and phenoxy to benzene and phenol. Specifically, EUV exposure of Ph 3 Sb(O 2 CCD 3 ) 2 creates d 0 -benzene and d 1 -phenol with >95% isotopic purity. Several mechanistic pathways are proposed and discussed.

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Acid Generation Efficiency of EUV PAGs via Low Energy Electron Exposure

Cited by 22 publications

References 18 publications

Reactivity of metal-oxalate EUV resists as a function of the central metal

Reactivity of metal-oxalate EUV resists as a function of the central metal

Isotopic Labeling Studies of EUV Photoresists Containing Antimony

EUV Mechanistic Studies of Antimony Resists

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