Formation and strengthening mechanisms of xonotlite in C3S-silica and C2S-silica powder systems under high temperature and pressure

As oil and gas exploration advances into more complex underground formations, oil-well cement, used to support bore casings, is at risk of mechanical failure. To clarify the strengthening mechanisms of silica powder, the hydration characteristics of C3S-silica and C2S-silica powder systems were stud...

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Veröffentlicht in:	Cement and concrete research 2022-07, Vol.157, p.106812, Article 106812
Hauptverfasser:	Wei, Tingcong, Wei, Fengqi, Zhou, Jinghong, Wu, Zhiqiang, Zhang, Chunmei, Zhuang, Jia, Cheng, Xiaowei
Format:	Artikel
Sprache:	eng
Schlagworte:	Boring Crystallization Dicalcium silicate High temperature Mechanical properties Oil exploration Silica powder Silicon dioxide Slaked lime Strengthening Strengthening mechanism Tricalcium silicate Xonotlite
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creator	Wei, Tingcong Wei, Fengqi Zhou, Jinghong Wu, Zhiqiang Zhang, Chunmei Zhuang, Jia Cheng, Xiaowei
description	As oil and gas exploration advances into more complex underground formations, oil-well cement, used to support bore casings, is at risk of mechanical failure. To clarify the strengthening mechanisms of silica powder, the hydration characteristics of C3S-silica and C2S-silica powder systems were studied at high temperature (230 °C) and pressure (20.7 MPa). The results show that microstructural coarsening is the primary reason for the poor mechanical properties of the cementitious materials. The formation of xonotlite included two sources: the crystallisation reaction of silica powder with C-S-H and the pozzolanic reaction of silica powder with calcium hydroxide. The CaO layer in C-S-H and calcium hydroxide provided a ‘Ca’ source for the formation of xonotlite. Q2 and Q3 Si units with a high polymerisation degree improve the high-temperature stability of xonotlite, while the dense structure formed by xonotlite improves the mechanical properties. For designing high-performance high-temperature resistant cement-based materials, xonotlite should preferably be generated by selecting crystalline silica powder.
doi_str_mv	10.1016/j.cemconres.2022.106812
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subjects	Boring Crystallization Dicalcium silicate High temperature Mechanical properties Oil exploration Silica powder Silicon dioxide Slaked lime Strengthening Strengthening mechanism Tricalcium silicate Xonotlite
title	Formation and strengthening mechanisms of xonotlite in C3S-silica and C2S-silica powder systems under high temperature and pressure
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