EUV photofragmentation study of hybrid nonchemically amplified resists containing antimony as an absorption enhancer

Moura, Cleverson Alves da Silva; Belmonte, Guilherme Kretzmann; Reddy, Pulikanti Guruprasad; Gonslaves, Kenneth E.; Weibel, Daniel Eduardo

doi:10.1039/c7ra12934c

Cited by 30 publications

(19 citation statements)

References 51 publications

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“…X-ray photoelectron spectroscopic (XPS) analysis of the electrodes exposed to air after 12 h of electroreduction and resting at an open circuit for 2.5 h until E oc reached ∼2.8 V vs Li app 0/+ showed no presence of Li 0 /Li 3 N, as expected (Figure S10a) but revealed a significant amount of Li 2 CO 3 21 (Figure S10b-d), which is most likely a product of reaction of Li 2 O/ LiOH with air CO 2 , as well as the original triflate salt (Figure S10e). 22 Additionally, Li 2 SO 3 (Figure S10f) 23 and small amounts of LiF (Figure S10e) 24 were found, both being likely products of the reductive decomposition of the OTf − anion. 20,22,25 XPS analysis of the electrode that was withdrawn from the cell as fast as possible after a 12 h test, with no subsequent measurements/resting and no exposure to air, revealed a qualitatively very similar composition except for the presence of LiOH instead of carbonate (Figure S10).…”

Section: ■ Results Discussionmentioning

confidence: 99%

Understanding the Factors Determining the Faradaic Efficiency and Rate of the Lithium Redox-Mediated N₂ Reduction to Ammonia

et al. 2021

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The lithium mediated reduction of N 2 is one of the only available approaches to electrochemical ammonia production at significant yields under ambient conditions. However, much remains to be investigated about the various electrochemical processes and side reactions that are involved. Herein, we have examined the effects of parameters including electrode potential, convection, N 2 pressure, and water content to refine and control the process. We demonstrate that a closely linear ammonia yield can be maintained during experiments up to 60 h in length, with approximately constant faradaic efficiency. This steady state operation appears to be preceded by a coating of the electrode surface with the products of the reductive electrolyte decomposition, such as LiF. We demonstrate ammonia yield rates above 1 nmol s −1 cm −2 and faradaic efficiencies as high as 60% through the improved control of the reaction conditions.

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Section: ■ Results Discussionmentioning

confidence: 99%

Understanding the Factors Determining the Faradaic Efficiency and Rate of the Lithium Redox-Mediated N₂ Reduction to Ammonia

et al. 2021

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“…The results presented here are very interesting taking into account our very recent work carried out using EUV excitation at 103.5 eV. 40,41 Absorption of EUV photons is a not resonant process, and a high stability of the aromatic section of the resists was found in spite of the studied resists containing heavy metal atoms to enhance the absorption of EUV photons. In particular, in the EUV irradiation of a polyarylene-sulfonium resist (PAS), 41 the aromatic sections of the polymer remained almost intact even after 15 min of continuous irradiation at 103.5 eV.…”

Section: Introductionmentioning

confidence: 60%

“…Irradiation by SR and surface oxidation of the thin resist surfaces followed the methodology already described. − , Briefly, specific transitions were selected, and for a fixed period of time, the polymer was irradiated under UHV conditions. After irradiation, the samples were transferred to a preparation chamber where they were exposed to pure oxygen at a pressure of 10 –3 Pa for 30 min to neutralize and oxidize the remaining radicals on the film surfaces.…”

Section: Methodsmentioning

confidence: 99%

“…In recent years, we have studied the photochemistry and oxidation mechanisms of several resists to be used in extreme ultraviolet lithography (EUVL) for the next generation of integrated circuits. − Those investigations were an attempt to understand the complex photofragmentation mechanisms after extreme ultraviolet (EUV) or inner shell excitation using SR. In one of our studies, a selective bond dissociation process was observed when the excitation energy was tuned to the C 1s → π CC * transition (285.3 eV) .…”

Section: Introductionmentioning

confidence: 99%

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Polarization Dependence in the Carbon K-Edge Photofragmentation of MAPDST Photoresist: An Experimental and Theoretical Study

et al. 2018

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The use of tunable soft X-rays from synchrotron radiation (SR) opens the possibility of inducing selective chemical bond scission because of its high localization in a chemical bond. The selective fragmentation of a potential extreme ultraviolet resist, poly(4-(methacryloyloxy) phenyldimethylsulfoniumtriflate) (MAPDST), was examined using inner shell-polarized SR excitation. Selective bond dissociation processes were studied using a combination of carbon K-edge excitation, angle-resolved irradiation, and near-edge X-ray absorption fine structure (NEXAFS) spectroscopy. Detailed theoretical calculations carried out with the FEFF9 modeling program allowed the interpretation of all the observed experimental features. NEXAFS results indicated that the aromatic group of the polymer lies parallel to the substrate surface. FEFF9 theoretical calculations confirmed the origin of the splitting of the main C 1s → πCC * resonances observed. The transition C 1s → παCC * (285.3 eV) can be associated with the four internal carbons of the aromatic ring. The transition C 1s → πβCC * (286.9 eV) was assigned to the carbon atoms attached to the oxygen and sulfur atoms. According to the theoretical calculations, the origin of the splitting is due to the different absolute energy of C 1s. The results showed a strong selective dissociation effect when the excitation energy was tuned to the C 1s → παCC * transition and the electric field vector of the photon was perpendicular to the substrate plane (grazing angle). On the contrary, other transitions were in general less affected. When the SR irradiation angle changed from grazing to normal incidence, the intensity of the C 1s → πCC * transitions was almost unaffected by 285.3 eV photons. The experimental results suggest that site-specific core excitation combined with the direction of the electric field vector of the incidence SR can efficiently control the localization of the photon energy to produce selective bond dissociation in MAPDST thin films. The results presented here can also be useful to guide new processing lithographic methods for extreme ultraviolet lithography using the polarization properties of light in ordered polymeric thin films.

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“…The presence of Sb‐F species is further confirmed by Sb 3d and Sb 4d spectra analysis (Figures S4 and S5). In 3d region, SbF 3 is confirmed at 531.7 (3d 5/2 ) and 541.0 eV (3d 3/2 ), while in 4d region the peaks at 35.8 (3d 5/2 ) and 37.0 eV (3d 3/2 ) are assigned to Sb‐F species 63 …”

Section: Resultsmentioning

confidence: 95%

Synergistic contribution on flame retardancy by charring production in high‐performance PEI/PBT/PTFE ternary blends: The role of PTFE

Vásquez-Rendón

Romero‐Sáez

Mena

et al. 2020

Polymers for Advanced Techs

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High‐performance binary blends between poly(ether imide) (PEI) and flame‐retardant poly(butylene terephthalate) (PBT) are modified with 5, 10, and 15 wt% of poly(tetrafluoroethylene) (PTFE) using a two‐step melt‐processing method. Morphology study reveals that PTFE does not interfere with PEI and PBT interfacial interaction during blends fabrication, and the dual‐phase inversion observed for binary PEI/PBT blends in previous works remains the same. Thermal degradation and fire resistance analyses show that charring layer formation is the major flame protection process and that PTFE enhances charring production for ternary blends. According to UL94 horizontal burning test, all blends are categorized as slow‐burning materials. Bomb calorimetry and thermal gravimetric analyses reveal that there is an interaction between PTFE with PEI and PBT phases, as well as with their degradation products. This phenomenon is explained by X‐ray photoelectron spectroscopy analysis, and it is attributable to Sb‐F species which enhances the formation of an intumescent layer.

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EUV photofragmentation study of hybrid nonchemically amplified resists containing antimony as an absorption enhancer

Abstract: Understanding the EUV photofragmentation mechanism in a highly sensitive hybrid n-CAR containing SbF6− as an absorption enhancer.

Cited by 30 publications

References 51 publications

Understanding the Factors Determining the Faradaic Efficiency and Rate of the Lithium Redox-Mediated N₂ Reduction to Ammonia

Understanding the Factors Determining the Faradaic Efficiency and Rate of the Lithium Redox-Mediated N₂ Reduction to Ammonia

Polarization Dependence in the Carbon K-Edge Photofragmentation of MAPDST Photoresist: An Experimental and Theoretical Study

Synergistic contribution on flame retardancy by charring production in high‐performance PEI/PBT/PTFE ternary blends: The role of PTFE

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EUV photofragmentation study of hybrid nonchemically amplified resists containing antimony as an absorption enhancer

Abstract: Understanding the EUV photofragmentation mechanism in a highly sensitive hybrid n-CAR containing SbF6− as an absorption enhancer.

Cited by 30 publications

References 51 publications

Understanding the Factors Determining the Faradaic Efficiency and Rate of the Lithium Redox-Mediated N2 Reduction to Ammonia

Understanding the Factors Determining the Faradaic Efficiency and Rate of the Lithium Redox-Mediated N2 Reduction to Ammonia

Polarization Dependence in the Carbon K-Edge Photofragmentation of MAPDST Photoresist: An Experimental and Theoretical Study

Synergistic contribution on flame retardancy by charring production in high‐performance PEI/PBT/PTFE ternary blends: The role of PTFE

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Product

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Understanding the Factors Determining the Faradaic Efficiency and Rate of the Lithium Redox-Mediated N₂ Reduction to Ammonia

Understanding the Factors Determining the Faradaic Efficiency and Rate of the Lithium Redox-Mediated N₂ Reduction to Ammonia