Sensitivity Analysis of the Catalysis Recombination Mechanism on Nanoscale Silica Surfaces

Li, He; Cui, Zhiliang; Sun, Xiangchun; Zhao, Jin; Wen, Dongsheng

doi:10.3390/nano12142370

Cited by 4 publications

(1 citation statement)

References 60 publications

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“…4c, the FTO/ZnO/Cu 2 O/Ag@SiO 2 photoanode possesses the smallest arc radius, indicating that the introduction of Ag@SiO 2 catalyst can decrease the charge transfer resistance to accelerate the photogenerated carrier transfer. 46 The four different Mott–Schottky curves in Fig. 4d also demonstrate that the FTO/ZnO/Cu 2 O/Ag@SiO 2 photoanode has the smallest slope and highest donor density, implying that the introduction of Ag@SiO 2 catalyst improves the photogenerated carrier transport.…”

Section: Resultsmentioning

confidence: 79%

Integration of a Cu₂O/ZnO heterojunction and Ag@SiO₂ into a photoanode for enhanced solar water oxidation

Zeng,

Gao,

Song

et al. 2024

RSC Adv.

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Section: Resultsmentioning

confidence: 79%

Integration of a Cu₂O/ZnO heterojunction and Ag@SiO₂ into a photoanode for enhanced solar water oxidation

Zeng,

Gao,

Song

et al. 2024

RSC Adv.

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Nano-roughness effect on the interfacial thermal oxidation and surface catalytical recombination characteristics for silicon carbide based materials under non-equilibrium flow

He,

Zhao,

Yao

et al. 2024

Applied Surface Science

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Influence of surface nanostructures on the catalytic recombination of hyperthermal non-equilibrium flow

Cao

et al. 2023

Physics of Fluids

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One of the key challenges for accurate prediction of hypersonic aerodynamic heating is the exothermic uncertainty due to the complex surface catalytic recombination effect, which is caused by the strong interactions between highly non-equilibrium dissociated gas and the thermal protection material surface. Employing engineered surface morphology to improve thermal protection effects has been proposed, but its effects on surface catalytic recombination remain unclear. To address this problem, this work employs the reactive molecular dynamics method to investigate the surface adsorption and recombination characteristics of continuous impingement of atomic oxygen upon eight different nano-structured silica surfaces. A parametric study of the influences of the gas incident angles and the surface structural parameters, i.e., roughness factor and surface fraction, is conducted. The results show that the surface catalytic recombination performance is very sensitive to the incident angle of the incoming gas, and the presence of nanostructures increases the recombination rate. The influence of surface morphology shows a complicated feature, where nanostructures with moderated fin height and high surface fraction are beneficial for the inhibition of surface recombination effects, leading to reduced exothermic heat release. Such microscopic revelation of the surface morphology effect is helpful for accurate prediction of aerodynamic heat and provides guidance for the surface engineering of optimized morphology to achieve improved thermal protection effect.

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Sensitivity Analysis of the Catalysis Recombination Mechanism on Nanoscale Silica Surfaces

Cited by 4 publications

References 60 publications

Integration of a Cu₂O/ZnO heterojunction and Ag@SiO₂ into a photoanode for enhanced solar water oxidation

Integration of a Cu₂O/ZnO heterojunction and Ag@SiO₂ into a photoanode for enhanced solar water oxidation

Nano-roughness effect on the interfacial thermal oxidation and surface catalytical recombination characteristics for silicon carbide based materials under non-equilibrium flow

Influence of surface nanostructures on the catalytic recombination of hyperthermal non-equilibrium flow

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Sensitivity Analysis of the Catalysis Recombination Mechanism on Nanoscale Silica Surfaces

Cited by 4 publications

References 60 publications

Integration of a Cu2O/ZnO heterojunction and Ag@SiO2 into a photoanode for enhanced solar water oxidation

Integration of a Cu2O/ZnO heterojunction and Ag@SiO2 into a photoanode for enhanced solar water oxidation

Nano-roughness effect on the interfacial thermal oxidation and surface catalytical recombination characteristics for silicon carbide based materials under non-equilibrium flow

Influence of surface nanostructures on the catalytic recombination of hyperthermal non-equilibrium flow

Contact Info

Product

Resources

About

Integration of a Cu₂O/ZnO heterojunction and Ag@SiO₂ into a photoanode for enhanced solar water oxidation

Integration of a Cu₂O/ZnO heterojunction and Ag@SiO₂ into a photoanode for enhanced solar water oxidation