Yanyuan Qi scite author profile

Ion irradiation is an alternative to heat treatment for transforming organic-inorganic thin films to a ceramic state. One major shortcoming in previous studies of ion-irradiated films is the assumption that constituent phases in ion-irradiated and heat-treated films are identical and that the ion irradiation effect is limited to changes in composition. In this study, we investigate the effects of ion irradiation on both the composition and structure of constituent phases and use the results to explain the measured elastic modulus of the films. The results indicated that the microstructure of the irradiated films consisted of carbon clusters within a silica matrix. It was found that carbon was present in a non-graphitic sp2-bonded configuration. It was also observed that ion irradiation caused a decrease in the Si-O-Si bond angle of silica, similar to the effects of applied pressure. A phase transformation from tetrahedrally bonded to octahedrally bonded silica was also observed. The results indicated the incorporation of carbon within the silica network. A combination of the decrease in Si-O-Si bond angle and an increase in the carbon incorporation within the silica network was found to be responsible for the increase in the elastic modulus of the films.

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Flexible electrochromic thin films with ultrafast responsion based on exfoliated V2O5 nanosheets/graphene oxide via layer-by-layer assembly

Qin

Zou

et al. 2020

Applied Surface Science

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Novel High-Performance and Low-Cost Electrochromic Prussian White Film

Yang

Peng

Jian

et al. 2022

ACS Appl. Mater. Interfaces

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Prussian white (PW), due to its low cost, easy synthesis, open structure, and fast ion extraction/interaction, is introduced to the electrochromic field. The PW films were successfully grown on indium tin oxide (ITO) glass by a facial hydrothermal method. Impressively, the PW film exhibits excellent electrochemical cycling stability without obvious decay over 10 000 cycles and a high coloration efficiency of 149.3 cm2 C–1. The film also provides the large optical transmittance contrast (over 70%) in a wide wavelength range of 650–800 nm. Furthermore, the PW film shows the rapid coloration and bleaching response. These results suggest that PW is a promising practical candidate of high-performance electrochromic material.

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Ultra-low permittivity HSM/PTFE composites for high-frequency microwave circuit application

Zhou²,

Shen³

et al. 2022

J Mater Sci: Mater Electron

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Surface modification of BMN particles with silane coupling agent for composites with PTFE

Luo

Shen

et al. 2017

Applied Surface Science

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Yanyuan Qi

Ion irradiation induced structural modifications and increase in elastic modulus of silica based thin films

Flexible electrochromic thin films with ultrafast responsion based on exfoliated V2O5 nanosheets/graphene oxide via layer-by-layer assembly

Novel High-Performance and Low-Cost Electrochromic Prussian White Film

Ultra-low permittivity HSM/PTFE composites for high-frequency microwave circuit application

Surface modification of BMN particles with silane coupling agent for composites with PTFE

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