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Auteurs principaux: Pengfei Zhang, Yue Zhan, Kang Guan, Ge Song, Junqin Shi, Xiaoli Fan, Qingfeng Zeng
Format: Artículo Open Access
Publié: Wiley 2026
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Accès en ligne:https://ceramics.onlinelibrary.wiley.com/doi/10.1111/jace.70708
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author Pengfei Zhang
Yue Zhan
Kang Guan
Ge Song
Junqin Shi
Xiaoli Fan
Qingfeng Zeng
author_facet Pengfei Zhang
Yue Zhan
Kang Guan
Ge Song
Junqin Shi
Xiaoli Fan
Qingfeng Zeng
Pengfei Zhang
Yue Zhan
Kang Guan
Ge Song
Junqin Shi
Xiaoli Fan
Qingfeng Zeng
collection Wiley Open Access
contents Multi‐Stage Decomposition Mechanism of Polycarbosilane During Pyrolysis by a ReaxFF Molecular Dynamics Study Pengfei Zhang Yue Zhan Kang Guan Ge Song Junqin Shi Xiaoli Fan Qingfeng Zeng Journal of the American Ceramic Society ABSTRACT Polycarbosilane (PCS) is a critical precursor for silicon carbide (SiC)‐based ceramics, although its atomistic pyrolysis mechanism remains insufficiently understood. In this study, large‐scale reactive molecular dynamics simulations using the ReaxFF force field were conducted to elucidate the product evolution and decomposition pathways of PCS under high‐temperature pyrolytic conditions. A crosslinked PCS model (93.75% crosslinking, density = 1.11 g/cm 3 ) was simulated under 2000–4000 K to quantitatively characterize molecular species evolution, bond dissociation sequences, and radical formation kinetics. The simulations revealed a multi‐stage decomposition mechanism involving initial Si─Si bond cleavage (≈ 2200 K), subsequent Si─C and C─C bond dissociation (2500–3200 K), and final stabilization into small thermodynamic species. Quantitatively, the formation of ─CH 3 and ─H radicals reached 340 and 200 molecules at 4000 K, corresponding to a CH 3 /H evolution ratio of 1.7, in close agreement with theoretical predictions (≈ 1.4). Product yield analysis showed that gaseous species such as H 2 and CH 4 dominate above 3500 K, while Si‐containing fragments (e.g., SiCH x ) decrease sharply, indicating a complete breakdown of the Si‐based framework. These results establish a direct correlation between bond dissociation energy hierarchy (Si─Si < Si─C < C─C) and temperature‐dependent product selectivity. This study provides the first quantitative atomistic validation of PCS pyrolysis stages and offers a mechanistic framework for optimizing preceramic polymer design and enhancing SiC ceramic yield. 10.1111/jace.70708 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1111/jace.70708
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id wiley_oa_10_1111_jace_70708
institution Wiley Open Access
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publishDate 2026
publisher Wiley
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spellingShingle Multi‐Stage Decomposition Mechanism of Polycarbosilane During Pyrolysis by a ReaxFF Molecular Dynamics Study
Pengfei Zhang
Yue Zhan
Kang Guan
Ge Song
Junqin Shi
Xiaoli Fan
Qingfeng Zeng
Journal of the American Ceramic Society
Multi‐Stage Decomposition Mechanism of Polycarbosilane During Pyrolysis by a ReaxFF Molecular Dynamics Study Pengfei Zhang Yue Zhan Kang Guan Ge Song Junqin Shi Xiaoli Fan Qingfeng Zeng Journal of the American Ceramic Society ABSTRACT Polycarbosilane (PCS) is a critical precursor for silicon carbide (SiC)‐based ceramics, although its atomistic pyrolysis mechanism remains insufficiently understood. In this study, large‐scale reactive molecular dynamics simulations using the ReaxFF force field were conducted to elucidate the product evolution and decomposition pathways of PCS under high‐temperature pyrolytic conditions. A crosslinked PCS model (93.75% crosslinking, density = 1.11 g/cm 3 ) was simulated under 2000–4000 K to quantitatively characterize molecular species evolution, bond dissociation sequences, and radical formation kinetics. The simulations revealed a multi‐stage decomposition mechanism involving initial Si─Si bond cleavage (≈ 2200 K), subsequent Si─C and C─C bond dissociation (2500–3200 K), and final stabilization into small thermodynamic species. Quantitatively, the formation of ─CH 3 and ─H radicals reached 340 and 200 molecules at 4000 K, corresponding to a CH 3 /H evolution ratio of 1.7, in close agreement with theoretical predictions (≈ 1.4). Product yield analysis showed that gaseous species such as H 2 and CH 4 dominate above 3500 K, while Si‐containing fragments (e.g., SiCH x ) decrease sharply, indicating a complete breakdown of the Si‐based framework. These results establish a direct correlation between bond dissociation energy hierarchy (Si─Si < Si─C < C─C) and temperature‐dependent product selectivity. This study provides the first quantitative atomistic validation of PCS pyrolysis stages and offers a mechanistic framework for optimizing preceramic polymer design and enhancing SiC ceramic yield. 10.1111/jace.70708 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Multi‐Stage Decomposition Mechanism of Polycarbosilane During Pyrolysis by a ReaxFF Molecular Dynamics Study
topic Journal of the American Ceramic Society
url https://ceramics.onlinelibrary.wiley.com/doi/10.1111/jace.70708