Radiation Effects in the Crystalline–Amorphous SiOC Polymer-Derived Ceramics: Insights from Experiments and Molecular Dynamics Simulation

Niu, Min; Gao, Hongfei; Zhao, Zihao; Su, Lei; Zhuang, Lei; Jia, Shuhai; Navrotsky, Alexandra

doi:10.1021/acsami.1c10917

Cited by 12 publications

(3 citation statements)

References 55 publications

(89 reference statements)

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“…The lower peak intensity of the Si–C bond means a smaller amount of SiC, while the high intensity of the O–Si–O bonds indicates the dominance of amorphous SiO 2 and other relevant SiOC tetrahedrals. The Si 2p spectra (Figure 6D) should also comprise various forms of SiO x C y between the SiO 4 and SiC 4 peaks, including SiO 2 C 2 , SiO 3 C, and SiOC 3 , 49 although they are not clearly observed based on the XPS peak deconvolution in Figure 6D. The high intensity of the overall peak demonstrates the dominance of the SiOC matrix.…”

Section: Resultsmentioning

confidence: 97%

Kr ion irradiation study of polymer‐derived SiFeOC–C–SiC nanocomposite

Singh

Shao

2022

J Am Ceram Soc.

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This study focuses on the pyrolysis and ion irradiation behaviors of polymer‐derived SiFeOC–C–SiC ceramic. The pyrolyzed material is composed of SiO2 and SiOC (amorphous), carbon (amorphous and turbostratic), and Fe3Si and β‐SiC (nanocrystalline). Irradiation was carried out at both room temperature and 600°C using 400 keV Kr ions with fluences of 4 × 1015 and 1 × 1016 ions cm−2, respectively. The Fe3Si and SiC nanocrystals are stable against irradiation up to 3 displacement per atom (dpa) at room temperature and up to 12 dpa at 600°C. The SiOC tetrahedrals show phase separation and minor carbothermal reduction. The high irradiation resistance and the dense, defect‐free amorphous microstructure of SiFeOC–C–SiC after prolonged irradiation demonstrate its great potential for advanced nuclear reactor applications.

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Section: Resultsmentioning

confidence: 97%

Kr ion irradiation study of polymer‐derived SiFeOC–C–SiC nanocomposite

Singh

Shao

2022

J Am Ceram Soc.

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“…[28][29][30][31][32] It is especially important to identify the effect of filler and corresponding structural modification on the thermodynamic stability of the respective ceramics, since stability determines propensity for phase separation and decomposition in PDCs. 5,[33][34][35][36][37] In the past, thermodynamic works investigated structure-stability relations in various PDC systems, including the effect of composition, mixed bonding, and pyrolysis temperature on the thermodynamic stability. 5,34,37 To this end, the present paper is the first work to systematically investigate the structural evolution and thermodynamic stabilization in PDCs incorporating Hf, Nb, and Ta.…”

Section: Introductionmentioning

confidence: 99%

“…As the use of PDC fillers increases, it is essential to understand how choice of filler influences composition as well as microstructure 28–32 . It is especially important to identify the effect of filler and corresponding structural modification on the thermodynamic stability of the respective ceramics, since stability determines propensity for phase separation and decomposition in PDCs 5,33–37 …”

Section: Introductionmentioning

confidence: 99%

Structural and thermodynamic analysis of metal filler incorporations in Si_aO_b(M)_cC_d polymer derived ceramics: Ta, Hf, Nb

Leonel

Scharrer

Singh

et al. 2023

Int J Applied Ceramic Tech

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This work systematically investigates the thermodynamic stability of SiaOb(M)cCd structures derived from polymeric precursors incorporating metal fillers: Ta, Nb, and Hf, at 1200 and 1500°C. Structural characterization of the polymer derived ceramics (PDCs) employs X‐ray diffraction, Fourier transform infrared spectroscopy, and X‐ray photoelectron spectroscopy. Enthalpies of formation relative to crystalline components (metal oxide, silica, silicon carbide, and graphite) are obtained from thermodynamic measurements by high temperature oxide melt solution calorimetry. The enthalpies of formation (∆H°f, comp) of Ta‐1200, Hf‐1200, Nb‐1200, Ta‐1500, Hf‐1500, and Nb‐1500 specimens are −137.82 ± 9.72, −256.31 ± 8.97, −82.80 ± 9.82, −182.80 ± 7.85, −292.54 ± 9.38, −224.98 ± 9.60 kJ/mol, respectively. Overall incorporation of Hf results in most thermodynamically stable structures at all synthesis temperatures. SiaOb(M)cCd specimens employing Nb fillers undergo the most stable structural evolution in this temperature range. The results indicate strong thermodynamic drive for carbothermal reduction of metal oxide domains. Incorporation of Ta provides the greatest stabilization of SiO3C mixed bonding environments. Ultimately, the choice of metal filler influences composition, structural evolution, and thermodynamic stability in PDCs.

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Multifunctional Metamaterial Microwave Blackbody with High‐Frequency Compatibility, Temperature Insensitivity, and Structural Scalability

Zhou

Pan

et al. 2022

Adv Funct Materials

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Compared with optical black, few attempts have focused on achieving broadband microwave blackbodies. In this study, all‐ceramic metamaterial microwave blackbodies are created by integrating a graded Gyroid shellular (GGS) metastructure design with additive manufacturing of polymer‐derived SiOC (PDCs‐SiOC) ceramics encapsulated by Si3N4 (SiOC@Si3N4). Hardly influenced by the destructive interference effect, as‐fabricated GGS‐structured SiOC@Si3N4 microwave blackbodies demonstrate a broadband microwave absorption (MA) above 83.6% (91.3% on average) across the entire X‐Ku band and encompassing higher frequencies above 18 GHz as well, together with the temperature insensitivity from room temperature to 500 °C. Based on the flexible electromagnetic tunability of PDCs‐SiOC, exceptional structural scalability is experimentally validated for metal‐doped modified CuSiOC and CoSiOC substrates with the same GGS metastructures, retaining high‐efficiency MA capability. Furthermore, attachment of perfectly reflecting metal backplanes further enhances the MA performance, with an ultrawide MA exceeding 67.9% (89.1% on average) achievable at 2.95–18 GHz for CoSiOC substrate. Meanwhile, the GGS‐structured SiOC@Si3N4 metamaterials possess additional multifunctional properties, such as good noise reduction performance as well as ultrahigh wear resistance. As a proof of concept, this study provides important guidance on achieving multifunctional coupling broadband MA characteristics by fully tapping the application potential of existing materials.

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Radiation Effects in the Crystalline–Amorphous SiOC Polymer-Derived Ceramics: Insights from Experiments and Molecular Dynamics Simulation

Cited by 12 publications

References 55 publications

Kr ion irradiation study of polymer‐derived SiFeOC–C–SiC nanocomposite

Kr ion irradiation study of polymer‐derived SiFeOC–C–SiC nanocomposite

Structural and thermodynamic analysis of metal filler incorporations in Si_aO_b(M)_cC_d polymer derived ceramics: Ta, Hf, Nb

Multifunctional Metamaterial Microwave Blackbody with High‐Frequency Compatibility, Temperature Insensitivity, and Structural Scalability

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Radiation Effects in the Crystalline–Amorphous SiOC Polymer-Derived Ceramics: Insights from Experiments and Molecular Dynamics Simulation

Cited by 12 publications

References 55 publications

Kr ion irradiation study of polymer‐derived SiFeOC–C–SiC nanocomposite

Kr ion irradiation study of polymer‐derived SiFeOC–C–SiC nanocomposite

Structural and thermodynamic analysis of metal filler incorporations in SiaOb(M)cCd polymer derived ceramics: Ta, Hf, Nb

Multifunctional Metamaterial Microwave Blackbody with High‐Frequency Compatibility, Temperature Insensitivity, and Structural Scalability

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Structural and thermodynamic analysis of metal filler incorporations in Si_aO_b(M)_cC_d polymer derived ceramics: Ta, Hf, Nb