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5. Heterogeneous Hydroxyl-Directed Hydrogenation: Control of Diastereoselectivity through Bimetallic Surface Composition

Author

Nicole J. Escorcia, Christina W. Li, William A. Swann, and Alexander J. Shumski

Subjects
inorganic chemicals, 010405 organic chemistry, Chemistry, Substrate (chemistry), General Chemistry, 010402 general chemistry, 01 natural sciences, Combinatorial chemistry, Catalysis, 0104 chemical sciences, Bimetallic nanoparticle, Homogeneous, Composition (visual arts), Selectivity, Bimetallic strip
Abstract

Directed hydrogenation, in which product selectivity is dictated by the binding of an ancillary directing group on the substrate to the catalyst, is typically catalyzed by homogeneous Rh and Ir com...

Published
2021
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6. Influence of the Defect Stability on n-Type Conductivity in Electron-Doped α- and β-Co(OH)2 Nanosheets

Author

Eve Y Martinez, Christina W. Li, and Kuixin Zhu

Subjects
010405 organic chemistry, Brucite, Chemistry, Doping, Oxide, chemistry.chemical_element, Crystal structure, engineering.material, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, Metal, Crystallography, chemistry.chemical_compound, visual_art, Vacancy defect, engineering, visual_art.visual_art_medium, Physical and Theoretical Chemistry, Cobalt, Coordination geometry
Abstract

Electronic doping of transition-metal oxides (TMOs) is typically accomplished through the synthesis of nonstoichiometric oxide compositions and the subsequent ionization of intrinsic lattice defects. As a result, ambipolar doping of wide-band-gap TMOs is difficult to achieve because the formation energies and stabilities of vacancy and interstitial defects vary widely as a function of the oxide composition and crystal structure. The facile formation of lattice defects for one carrier type is frequently paired with the high-energy and unstable generation of defects required for the opposite carrier polarity. Previous work from our group showed that the brucite (β-phase) layered metal hydroxides of Co and Ni, intrinsically p-type materials in their anhydrous three-dimensional forms, could be n-doped using a strong chemical reductant. In this work, we extend the electron-doping study to the α polymorph of Co(OH)2 and elucidate the defects responsible for n-type doping in these two-dimensional materials. Through structural and electronic comparisons between the α, β, and rock-salt structures within the cobalt (hydr)oxide family of materials, we show that both layered structures exhibit facile formation of anion vacancies, the necessary defect for n-type doping, that are not accessible in the cubic CoO structure. However, the brucite polymorph is much more stable to reductive decomposition in the presence of doped electrons because of its tighter layer-to-layer stacking and octahedral coordination geometry, which results in a maximum conductivity of 10-4 S/cm, 2 orders of magnitude higher than the maximum value attainable on the α-Co(OH)2 structure.

Published
2021
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7. Superradiance and Exciton Delocalization in Perovskite Quantum Dot Superlattices

Author

Daria D. Blach, Victoria A. Lumsargis, Daniel E. Clark, Chern Chuang, Kang Wang, Letian Dou, Richard D. Schaller, Jianshu Cao, Christina W. Li, and Libai Huang

Subjects
Mechanical Engineering, General Materials Science, Bioengineering, General Chemistry, Condensed Matter Physics
Abstract

Achieving superradiance in solids is challenging due to fast dephasing processes from inherent disorder and thermal fluctuations. Perovskite quantum dots (QDs) are an exciting class of exciton emitters with large oscillator strength and high quantum efficiency, making them promising for solid-state superradiance. However, a thorough understanding of the competition between coherence and dephasing from phonon scattering and energetic disorder is currently unavailable. Here, we present an investigation of exciton coherence in perovskite QD solids using temperature-dependent photoluminescence line width and lifetime measurements. Our results demonstrate that excitons are coherently delocalized over 3 QDs at 11 K in superlattices leading to superradiant emission. Scattering from optical phonons leads to the loss of coherence and exciton localization to a single QD at temperatures above 100 K. At low temperatures, static disorder and defects limit exciton coherence. These results highlight the promise and challenge in achieving coherence in perovskite QD solids.

Published
2022

8. Controlling the Co–S coordination environment in Co-doped WS2 nanosheets for electrochemical oxygen reduction

Author

Wei Hong, Erika Meza, and Christina W. Li

Subjects
inorganic chemicals, biology, Renewable Energy, Sustainability and the Environment, Chemistry, Coordination number, Active site, chemistry.chemical_element, 02 engineering and technology, General Chemistry, Electrolyte, Overpotential, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Cobalt sulfide, 0104 chemical sciences, Catalysis, chemistry.chemical_compound, Chemical engineering, biology.protein, General Materials Science, 0210 nano-technology, Cobalt
Abstract

Cobalt sulfide nanomaterials are among the most active and stable catalysts for the electrocatalytic oxygen reduction reaction in pH 7 electrolyte. However, due to the complexity and dynamism of the catalytic surfaces in cobalt sulfide bulk materials, it is challenging to identify and tune the active site structure in order to achieve low overpotential oxygen reduction reactivity. In this work, we synthesize isolated Co sites supported on colloidal WS2 nanosheets and develop a synthetic strategy to rationally control the first-shell coordination environment surrounding the adsorbed Co active sites. By studying Co–WS2 materials with a range of Co–S coordination numbers, we are able to identify the optimal active site for pH 7 oxygen reduction catalysis, which comprises cobalt atoms bound to the WS2 support with a Co–S coordination number of 3–4. The optimized Co–WS2 material exhibits an oxygen reduction onset potential of 0.798 V vs. RHE, which is comparable to the most active bulk phases of cobalt sulfide in neutral electrolyte conditions.

Published
2021
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9. Modulating the Structure and Hydrogen Evolution Reactivity of Metal Chalcogenide Complexes through Ligand Exchange onto Colloidal Au Nanoparticles

Author

Jeffrey S. Lowe, Jeffrey Greeley, Eric Z. Liu, Alexander J. Shumski, Vamakshi Yadav, and Christina W. Li

Subjects
chemistry.chemical_compound, chemistry, Chemical engineering, Ligand, Chalcogenide, Nanoparticle, Reactivity (chemistry), General Chemistry, Electrochemistry, Molybdenum disulfide, Catalysis, Amorphous solid
Abstract

The interaction between catalyst and support is well known to influence the reactivity and stability of heterogeneous catalysts, and electrochemical hydrogen evolution catalysts based on amorphous ...

Published
2020
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10. Reversible Electron Doping of Layered Metal Hydroxide Nanoplates (M = Co, Ni) Using n-Butyllithium

Author

Christina W. Li, Eve Y Martinez, and Kuixin Zhu

Subjects
Materials science, Metal hydroxide, Mechanical Engineering, Doping, Inorganic chemistry, Intercalation (chemistry), Oxide, Bioengineering, Electron donor, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Metal, chemistry.chemical_compound, chemistry, visual_art, Vacancy defect, visual_art.visual_art_medium, Hydroxide, General Materials Science, 0210 nano-technology
Abstract

Ambipolar doping of metal oxides is critical toward broadening the functionality of semiconducting oxides in electronic devices. Most metal oxides, however, show a strong preference for a single doping polarity due to the intrinsic stability of particular defects in an oxide lattice. In this work, we demonstrate that layered metal hydroxide nanomaterials of Co and Ni, which are intrinsically p-doped in their anhydrous rock salt form, can be n-doped using n-BuLi as a strong electron donor. A combination of X-ray characterization techniques reveal that hydroxide vacancy formation, Li+ adsorption, and varying degrees of electron delocalization are responsible for the stability of injected electrons. The doped electrons induce conductivity increases of 4-6 orders of magnitude relative to the undoped M(OH)2. We anticipate that chemical electron doping of layered metal hydroxides may be a general strategy to increase carrier concentration and stability for n-doping of intrinsically p-type metal oxides.

Published
2020
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11. Colloidal Synthesis of Well-Defined Bimetallic Nanoparticles for Nonoxidative Alkane Dehydrogenation

Author

Jeffrey T. Miller, Christina W. Li, Nicole J. Libretto, and Nicole J. Escorcia

Subjects
Alkane, chemistry.chemical_classification, 010405 organic chemistry, Chemistry, Nanoparticle, General Chemistry, 010402 general chemistry, Heterogeneous catalysis, 01 natural sciences, Combinatorial chemistry, Catalysis, 0104 chemical sciences, Dehydrogenation, Well-defined, Bimetallic strip, Colloidal synthesis
Abstract

Precise synthesis and characterization of bimetallic nanoparticles are critical toward understanding structure–activity relationships in alkane dehydrogenation catalysis. Traditional synthetic meth...

Published
2020
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12. Solution-Phase Activation and Functionalization of Colloidal WS2 Nanosheets with Ni Single Atoms

Author

Erika Meza, Christina W. Li, and Rosa E. Diaz

Subjects
Materials science, Tungsten disulfide, General Engineering, Oxygen evolution, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Solution phase, 0104 chemical sciences, Catalysis, Colloid, chemistry.chemical_compound, Chemical engineering, chemistry, Surface modification, General Materials Science, 0210 nano-technology, Colloidal synthesis
Abstract

Single-atom functionalization of transition-metal dichalcogenide (TMD) nanosheets is a powerful strategy to tune the optical, magnetic, and catalytic properties of two-dimensional materials. In thi...

Published
2020
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13. Surface functionalization of Pt nanoparticles with metal chlorides for bifunctional CO oxidation

Author

Christina W. Li and Eve Y Martinez

Subjects
010405 organic chemistry, Oxide, Nanoparticle, Overpotential, 010402 general chemistry, 01 natural sciences, Catalyst poisoning, 0104 chemical sciences, Catalysis, Inorganic Chemistry, chemistry.chemical_compound, Adsorption, Transition metal, chemistry, Chemical engineering, Materials Chemistry, Physical and Theoretical Chemistry, Bifunctional
Abstract

Incorporation of a metal oxide or hydroxide species into Pt-based electrocatalysts has been shown to lower the overpotential required to oxidatively remove carbon monoxide from the catalyst surface, a reaction that is critical to preventing catalyst poisoning and deactivation in fuel cell devices. In this work, we report a general synthetic method toward Pt-metal oxide composite nanoparticles via the adsorption of metal halide ligands onto 1–2 nm colloidal Pt nanoparticles. Pt-metal oxide composite nanoparticles spanning across the first-row transition metals and post-transition metals are synthesized and characterized with transmission electron microscopy and energy dispersive X-ray scattering. CO stripping and steady-state CO oxidation experiments reveal that Mn, Fe, Co, Ni, and In oxides are capable of participating in the catalysis as a bifunctional partner and reduce the overpotential required for CO electrooxidation by ∼200 mV relative to pure Pt.

Published
2019
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14. Microstructural Evolution of Au@Pt Core–Shell Nanoparticles under Electrochemical Polarization

Author

Wei Hong and Christina W. Li

Subjects
Materials science, Nanoparticle, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Microstructure, Electrochemistry, Electrocatalyst, 01 natural sciences, 0104 chemical sciences, Catalysis, Metal, Chemical engineering, visual_art, visual_art.visual_art_medium, General Materials Science, 0210 nano-technology, Polarization (electrochemistry), Bimetallic strip
Abstract

Understanding the microstructural evolution of bimetallic Pt nanoparticles under electrochemical polarization is critical to developing durable fuel cell catalysts. In this work, we develop a colloidal synthetic method to generate core-shell Au@Pt nanoparticles of varying surface Pt coverages to understand how as-synthesized bimetallic microstructure influences nanoparticle structural evolution during formic acid oxidation. By comparing the electrochemical and structural properties of our Au@Pt core-shells with bimetallic AuPt alloys at various stages in catalytic cycling, we determine that these two structures evolve in divergent ways. In core-shell nanoparticles, Au atoms from the core migrate outward onto the surface, generating transient "single-atom" Pt active sites with high formic acid oxidation activity. Metal migration continues until Pt is completely encapsulated by Au, and catalytic reactivity ceases. In contrast, AuPt alloys undergo surface dealloying and significant leaching of Pt out of the nanoparticle. Elucidating the dynamic restructuring processes responsible for high electrocatalytic reactivity in Pt bimetallic structures will enable better design and predictive synthesis of nanoparticle catalysts that are both active and stable.

Published
2019
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15. Influence of the Defect Stability on n-Type Conductivity in Electron-Doped α- and β-Co(OH)

Author

Eve Y, Martinez, Kuixin, Zhu, and Christina W, Li

Abstract

Electronic doping of transition-metal oxides (TMOs) is typically accomplished through the synthesis of nonstoichiometric oxide compositions and the subsequent ionization of intrinsic lattice defects. As a result, ambipolar doping of wide-band-gap TMOs is difficult to achieve because the formation energies and stabilities of vacancy and interstitial defects vary widely as a function of the oxide composition and crystal structure. The facile formation of lattice defects for one carrier type is frequently paired with the high-energy and unstable generation of defects required for the opposite carrier polarity. Previous work from our group showed that the brucite (β-phase) layered metal hydroxides of Co and Ni, intrinsically p-type materials in their anhydrous three-dimensional forms, could be n-doped using a strong chemical reductant. In this work, we extend the electron-doping study to the α polymorph of Co(OH)

Published
2021

16. Reversible Electron Doping of Layered Metal Hydroxide Nanoplates (M = Co, Ni) Using

Author

Eve Y, Martinez, Kuixin, Zhu, and Christina W, Li

Abstract

Ambipolar doping of metal oxides is critical toward broadening the functionality of semiconducting oxides in electronic devices. Most metal oxides, however, show a strong preference for a single doping polarity due to the intrinsic stability of particular defects in an oxide lattice. In this work, we demonstrate that layered metal hydroxide nanomaterials of Co and Ni, which are intrinsically p-doped in their anhydrous rock salt form, can be n-doped using

Published
2020

17. Systematic Control of Redox Properties and Oxygen Reduction Reactivity through Colloidal Ligand-Exchange Deposition of Pd on Au

Author

Christina W. Li, Xueyong Zhang, Xiaoxi Huang, and Alexander J. Shumski

Subjects
Chemistry, Inorganic chemistry, Oxide, Nanoparticle, 02 engineering and technology, General Chemistry, Overpotential, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, Redox, Catalysis, 0104 chemical sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, Adsorption, Monolayer, engineering, Noble metal, 0210 nano-technology
Abstract

Core-shell nanoparticles of Au@Pd with precise submonolayer, monolayer, or multilayer structure were synthesized using ligand-exchange reactions of palladate ions onto colloidal Au nanocrystals. Decoupling the palladate adsorption step from the subsequent reduction enables excellent precision, uniformity, and tunability in the Pd shell thickness. The redox properties of the surface Pd are directly correlated to the thickness of the Pd shell with a+200 mV shift in the PdO reduction potential for submonolayer Au@Pd nanoparticles compared to pure Pd. Using these precisely controlled core-shell materials, the oxygen reduction catalytic activity can be directly correlated to PdO reduction potential and Pd surface coverage on Au. When the Pd oxide reduction peak is shifted by +240 mV compared to pure Pd, a 50 mV reduction in overpotential and a 4-fold increase in kinetic current density for oxygen reduction are observed. Colloidal ligand-exchange synthesis may be particularly useful for noble metal core-shell catalysts as a strategy to subtly tune the electronic properties of surface atoms in order to lower overpotential and increase catalytic turnover.

Published
2018
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18. Solution-Phase Activation and Functionalization of Colloidal WS

Author

Erika, Meza, Rosa E, Diaz, and Christina W, Li

Abstract

Single-atom functionalization of transition-metal dichalcogenide (TMD) nanosheets is a powerful strategy to tune the optical, magnetic, and catalytic properties of two-dimensional materials. In this work, we demonstrate a simple solution-phase method to generate nucleophilic sulfide sites on colloidal WS

Published
2020

19. Electroreduction of carbon monoxide to liquid fuel on oxide-derived nanocrystalline copper

Author

Jim Ciston, Christina W. Li, and Matthew W. Kanan

Subjects
chemistry.chemical_compound, Multidisciplinary, Chemistry, Inorganic chemistry, Oxide, Reversible hydrogen electrode, Electrochemistry, Electrocatalyst, Oxygenate, Faraday efficiency, Liquid fuel, Catalysis
Abstract

The electrochemical conversion of CO and H2O into liquid fuel is made feasible at modest potentials with the use of oxide-derived nanocystalline Cu as the catalyst. Renewable electricity is often produced when it is not needed. If the surplus could be harnessed to drive the conversion of CO2 and water into liquid fuel, the energy would not go to waste and a use would be found for CO2 produced by carbon capture. All this requires efficient electrocatalysts that reduce CO2 not only to CO, but also further into fuel chemicals. Copper does this but with low efficiency and selectivity. Christina Li et al. now show that the intrinsic catalytic properties of copper can be improved by producing it from its oxide as interconnected nanocrystallites. Their enhanced catalyst generates primarily ethanol, demonstrating that a two-step conversion of CO2 to liquid fuel powered by renewable electricity might be possible. The electrochemical conversion of CO2 and H2O into liquid fuel is ideal for high-density renewable energy storage and could provide an incentive for CO2 capture. However, efficient electrocatalysts for reducing CO2 and its derivatives into a desirable fuel1,2,3 are not available at present. Although many catalysts4,5,6,7,8,9,10,11 can reduce CO2 to carbon monoxide (CO), liquid fuel synthesis requires that CO is reduced further, using H2O as a H+ source. Copper (Cu) is the only known material with an appreciable CO electroreduction activity, but in bulk form its efficiency and selectivity for liquid fuel are far too low for practical use. In particular, H2O reduction to H2 outcompetes CO reduction on Cu electrodes unless extreme overpotentials are applied, at which point gaseous hydrocarbons are the major CO reduction products12,13. Here we show that nanocrystalline Cu prepared from Cu2O (‘oxide-derived Cu’) produces multi-carbon oxygenates (ethanol, acetate and n-propanol) with up to 57% Faraday efficiency at modest potentials (–0.25 volts to –0.5 volts versus the reversible hydrogen electrode) in CO-saturated alkaline H2O. By comparison, when prepared by traditional vapour condensation, Cu nanoparticles with an average crystallite size similar to that of oxide-derived copper produce nearly exclusive H2 (96% Faraday efficiency) under identical conditions. Our results demonstrate the ability to change the intrinsic catalytic properties of Cu for this notoriously difficult reaction by growing interconnected nanocrystallites from the constrained environment of an oxide lattice. The selectivity for oxygenates, with ethanol as the major product, demonstrates the feasibility of a two-step conversion of CO2 to liquid fuel that could be powered by renewable electricity.

Published
2014
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20. Finite-Size Effects in O and CO Adsorption for the Late Transition Metals

Author

Felix Mbuga, Di Wu, Chin Chun Ooi, Lin Li, Thomas P. Brennan, Amit Kushwaha, Lars C. Grabow, Andrew J. Medford, Bonggeun Shong, Jens K. Nørskov, Andrew A. Peterson, and Christina W. Li

Subjects
Chemistry, Coordination number, Inorganic chemistry, General Chemistry, Catalysis, Metal, Crystal, Crystallography, Adsorption, Transition metal, visual_art, visual_art.visual_art_medium, Cluster (physics), Density functional theory
Abstract

Gold is known to become significantly more catalytically active as its particle size is reduced, and other catalysts are also known to exhibit finite-size effects. To understand the trends related to finite-size effects, we have used density functional theory to study adsorption of representative adsorbates, CO and O, on the late transition metals Co, Ni, Cu, Ir, Pd, Ag, Rh, Pt and Au. We studied adsorption energies and geometries on 13-atom clusters and compared them to the fcc(111) and fcc(211) crystal facets. In all cases, adsorbates were found to bind significantly more strongly to the 13-atom clusters than to the extended surfaces. The binding strength of both adsorbates were found to correlate very strongly with the average coordination number of the metal atoms to which the adsorbate binds, indicating that the finite-size effects in bonding are not specific to gold.

Published
2012
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21. Aqueous CO2 reduction at very low overpotential on oxide-derived Au nanoparticles

Author

Matthew W. Kanan, Christina W. Li, and Yihong Chen

Subjects
Carbon Monoxide, Aqueous solution, Formates, Surface Properties, Inorganic chemistry, Oxide, Nanoparticle, Metal Nanoparticles, Water, Oxides, General Chemistry, Overpotential, Carbon Dioxide, Biochemistry, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Electrode, Gold, Particle Size, Selectivity, Oxidation-Reduction, Electrochemical reduction of carbon dioxide
Abstract

Carbon dioxide reduction is an essential component of many prospective technologies for the renewable synthesis of carbon-containing fuels. Known catalysts for this reaction generally suffer from low energetic efficiency, poor product selectivity, and rapid deactivation. We show that the reduction of thick Au oxide films results in the formation of Au nanoparticles ("oxide-derived Au") that exhibit highly selective CO(2) reduction to CO in water at overpotentials as low as 140 mV and retain their activity for at least 8 h. Under identical conditions, polycrystalline Au electrodes and several other nanostructured Au electrodes prepared via alternative methods require at least 200 mV of additional overpotential to attain comparable CO(2) reduction activity and rapidly lose their activity. Electrokinetic studies indicate that the improved catalysis is linked to dramatically increased stabilization of the CO(2)(•-) intermediate on the surfaces of the oxide-derived Au electrodes.

Published
2012

22. CO2 reduction at low overpotential on Cu electrodes resulting from the reduction of thick Cu2O films

Author

Christina W. Li and Matthew W. Kanan

Subjects
Chemistry, Annealing (metallurgy), Metallurgy, Analytical chemistry, General Chemistry, Surface finish, Overpotential, Biochemistry, Catalysis, Colloid and Surface Chemistry, Electrode, Crystallite, Metal electrodes, FOIL method
Abstract

Modified Cu electrodes were prepared by annealing Cu foil in air and electrochemically reducing the resulting Cu(2)O layers. The CO(2) reduction activities of these electrodes exhibited a strong dependence on the initial thickness of the Cu(2)O layer. Thin Cu(2)O layers formed by annealing at 130 °C resulted in electrodes whose activities were indistinguishable from those of polycrystalline Cu. In contrast, Cu(2)O layers formed at 500 °C that were ≥~3 μm thick resulted in electrodes that exhibited large roughness factors and required 0.5 V less overpotential than polycrystalline Cu to reduce CO(2) at a higher rate than H(2)O. The combination of these features resulted in CO(2) reduction geometric current densities1 mA/cm(2) at overpotentials0.4 V, a higher level of activity than all previously reported metal electrodes evaluated under comparable conditions. Moreover, the activity of the modified electrodes was stable over the course of several hours, whereas a polycrystalline Cu electrode exhibited deactivation within 1 h under identical conditions. The electrodes described here may be particularly useful for elucidating the structural properties of Cu that determine the distribution between CO(2) and H(2)O reduction and provide a promising lead for the development of practical catalysts for electrolytic fuel synthesis.

Published
2012

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