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| Experimental Study on Physicochemical Properties and Hydration Activity of Modified Magnesium Slag |
| SUN Wei-ji1, LIU Lang1, 2*, HOU Dong-zhuang3, QIU Hua-fu1, 2, TU Bing-bing4, XIN Jie1 |
1. College of Energy Engineering, Xi'an University of Science and Technology, Xi'an 710054, China
2. Key Laboratory of Western Mine Exploitation and Hazard Prevention, Ministry of Education, Xi'an 710054, China
3. College of Geology and Environment, Xi'an University of Science and Technology, Xi'an 710054, China
4. College of Science, Xi'an University of Science and Technology, Xi'an 710054, China
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Abstract The resource utilization of magnesium slag is an urgent problem. This paper uses magnesium slag and modified magnesium slag as the main cementing materials, and magnesium slag based cementing materials (UCGB) and modified magnesium slag based cementing materials (MCGB) are prepared by adding fly ash. The flow characteristics, mechanical properties, microstructure and hydration characteristics of the filling materials are compared and analyzed. The results show that when the mixing ratio of modified magnesium slag and fly ash is 4/1, the prepared MCGB sample has excellent mechanical properties, and the uniaxial compressive strength is up to 4.213 MPa after curing for 28 days. With the growth of curing age, MCGB sample hydration produces a large number of hydration products such as C-S-H gel, Ca(OH)2 crystal and filamentous Ettringite, which are interwoven and agglomerated with other silicate oxides ([Fe, Mg, Al]2.5[Si, Al]2O5[OH]4). Filling in the pores and holes inside the sample is helpful in improving the mechanical properties and durability of the MCGB sample. Compared with the MCGB sample, the mechanical properties of the UCGB sample are not ideal. The early strength of the UCGB sample is low, and only a small amount of Ettringite and Ca(OH)2 crystals are produced by hydration, forming a porous microstructure. In addition, the infrared spectrum curve analysis shows that the characteristic frequency of β-C2S appears near 997 cm-1 of the modified magnesium slag, while the characteristic identification spectrum band of γ-C2S appears near 820 cm-1 of the magnesium slag. Combined with the X-ray spectrum analysis, the mineral phase of the modified magnesium slag mainly changes to β-C2S. However, the mineral phase of the original magnesium slag is mainly γ-C2S, which has almost no hydration activity, so it is unsuitable for mining as a cementitious material. Therefore, this study aims to provide scientific basis and guidance for the preparation of new mine cementitious materials based on modified magnesium slag.
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Received: 2022-05-17
Accepted: 2022-10-27
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Corresponding Authors:
LIU Lang
E-mail: liulang@xust.edu.cn
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[1] QIAN Ming-gao, MIAO Xie-xing, XU Jia-lin(钱鸣高, 缪协兴, 许家林). Journal of China Coal Society(煤炭学报), 2007, 32(1): 1.
[2] Chen Qiusong, Zhang Qinli, Wang Xinmin, et al. Environmental Earth Sciences, 2016, 75(14): 1099.
[3] LI Jing-kuan, QIAO Xiao-lei, JIN Yan(李经宽, 乔晓磊, 金 燕) . Journal of Taiyuan University of Technology(太原理工大学学报), 2008,(6): 573.
[4] LI Yong-ling, LIANG Peng-xiang, FAN Yuan, et al(李咏玲, 梁鹏翔, 范 远, 等). Environmental Chemistry(环境化学), 2015, 34(11): 2077.
[5] Liu Lang, Ruan Shishan, Qi Chongchong, et al. Journal of Cleaner Production, 2020, 279: 123684.
[6] PAN Xiao-lin, PEI Jian-nan, ZHANG Can, et al(潘晓林, 裴健男, 张 灿, 等). The Chinese Journal of Nonferrous Metals(中国有色金属学报), 2020, 30(9): 2136.
[7] LI Yong-ling, GE Tian, CHENG Fang-qin(李咏玲, 戈 甜, 程芳琴). Inorganic Chemicals Industry(无机盐工业), 2016, 48(3): 52.
[8] Seung Heun Lee, Hong Joo Kim, Etsuo Sakai, et al. Cement and Concrete Research, 2003, 33(5): 763.
[9] ZHU Ming, XUE Gao-rui, MU Yuan-dong(朱 明, 雪高瑞, 穆元冬). Bulletin of the Chinese Ceramic Society(硅酸盐通报), 2017, 36(9): 3036.
[10] REN Ang, FENG Guo-rui, GUO Yu-xia, et al(任 昂, 冯国瑞, 郭育霞, 等). Journal of China Coal Society(煤炭学报), 2014, 39(12): 2374.
[11] Warda Ashraf. Construction and Building Materials, 2018, 185: 617.
[12] FENG Chun-hua, LI Dong-xu(冯春花, 李东旭). Bulletin of the Chinese Ceramic Society(硅酸盐通报), 2015, 34(11): 3202.
[13] Kanchanason V, Plank J. Cement & Concrete Research, 2017, 102: 90.
[14] Harutyunyan V S, Kirchheim A P, Monteiro P J M, et al. Journal of Materials Science, 2009, 44(4): 962.
[15] CHENG Hai-yong, WU Ai-xiang, WANG Yi-ming, et al(程海勇, 吴爱祥, 王贻明, 等). Chinese Journal of Rock Mechanics and Engineering(岩石力学与工程学报), 2016, 35(S2): 4241.
[16] Fall M, Célestin J C, Pokharel M, et al. Engineering Geology, 2010, 114(3): 397.
[17] LI Xiang, YAN Pei-yu(李 响, 阎培渝). Journal of Building Materials(建筑材料学报), 2010, 13(6): 787.
[18] Zhang Na, Liu Xiaoming, Sun Henghu, et al. Cement and Concrete Research, 2011, 41(3): 270.
[19] Zhang Na, Li Hongxu, Zhao Yazhao, et al. Journal of Hazardous Materials, 2016, 306: 67.
[20] Wang Yaguang, Han Fenglan, Mu Jingqiu. Construction and Building Materials, 2018, 160: 818.
[21] WEN Xu-hui, ZHANG Jin-cai, LIAO Hong-qiang, et al(温旭辉, 张金才, 廖洪强, 等). Fly Ash Comprehensive Utilization(粉煤灰综合利用), 2019,(6): 11. |
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