石墨烯量子点对蛇纹石混凝土力学性能及微结构的影响

杨昭; 石建军; 张志恒; 陈磊

石墨烯量子点对蛇纹石混凝土力学性能及微结构的影响

南华大学　土木工程学院, 衡阳 421001

基金项目: 湖南省自然科学基金(14 JJ2083)；湖南省科技厅重点研发计划项目(2015 JC3090)；湖南省研究生科研创新项目资助(CX20230973)

详细信息

通讯作者:
石建军，博士，教授，硕士生导师，研究方向为高性能混凝土及新型组合结构等　E-mail: sjj6621@163.com

中图分类号: TU528.35;TB332
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- 文章访问数: 120
- HTML全文浏览量: 33
- 被引次数: 0
出版历程
- 收稿日期: 2023-11-13
- 修回日期: 2023-12-18
- 录用日期: 2023-12-28
- 网络出版日期: 2024-01-20

Effect of graphene quantum dots on mechanical properties and microstructure of serpentine concrete

School of Civil Engineering, University of South China, Hengyang 421001, China

Funds: Hunan Provincial Natural Science Foundation (14 JJ2083); Key Research and Development Projects of Hunan Provincial Science and Technology Department (2015 JC3090); Postgraduate Scientific Research Innovation Project of Hunan Province (CX20230973)

摘要

摘要: 为了考察石墨烯量子点(GQDs)作为外掺料改善蛇纹石混凝土性能的可行性，研究了25、150、300、450和600 ℃时GQDs掺量对蛇纹石混凝土强度、结晶水损失率和微结构的影响。结果表明：室温(25 ℃)下，蛇纹石混凝土强度随GQDs掺量的增加而提升，当掺量为0.12wt%时，改善效果最佳，其7、28 d抗压强度和28 d劈裂抗拉强度分别较基准组提高了26.4%、20.9%和27.7%；加热期间，与未掺GQDs的蛇纹石混凝土相比，掺入0.12wt%的GQDs使蛇纹石混凝土结晶水损失率降低了1.8%~20.0%，抗压强度和劈裂抗拉强度分别增加了18.0%~34.0%和29.4%~39.8%；微观试验表明高温环境促使蛇纹石混凝土水化，而GQDs拥有较好的导热性和纳米填充性，在二者共同作用下显著提高了蛇纹石混凝土的微观致密度，且300 ℃时致密度最高。
- 蛇纹石混凝土 /
- 石墨烯量子点 /
- 结晶水 /
- 力学性能 /
- 高温稳定性 /
- 微结构
Abstract: In order to explore the feasibility of using graphene quantum dots (GQDs) as admixtures to improve the properties of serpentine concrete, effects of GQDs dosage on strength, crystal water loss rate, and microstructure of serpentine concrete were investigated at 25, 150, 300, 450, and 600℃. The results show that strength of serpentine concrete at room temperature (25 ℃) is enhanced with the increase in the dosage of GQDs, and the best enhancement is achieved when the dosage is 0.12wt%, and its 7 d and 28 d compressive strength and 28 d splitting tensile strength are increased by 26.4%, 20.9%, and 27.7%, respectively, compared with the baseline group. The addition of 0.12wt% GQDs reduces the crystal water loss rate of serpentine concrete by 1.8%~20.0%, and increases the compressive strength and splitting tensile strength by 18.0%~34.0% and 29.4%~39.8%, respectively, as compared to serpentine concrete without GQDs during the entire heating period. Microscopic tests show that high temperature environment promotes the hydration of serpentine concrete, as well as GQDs possess better thermal conductivity and nano-filling properties, which together significantly improve the micro-density of serpentine concrete, and the micro-density is highest at 300 ℃.
- serpentine concrete /
- GQDs /
- crystal water /
- mechanical properties /
- high temperature stability /
- microstructure

HTML全文

图 1 石墨烯量子点(GQDs)微观表征结果

Figure 1. Results of graphene quantum dots (GQDs) microscopic characterization

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图 2 不同GQDs掺量对蛇纹石混凝土抗压强度的影响：(a)抗压强度值；(b)抗压强度增长率

Figure 2. Compressive strength of serpentine concrete with different dosage of GQDs: (a) Compressive strength value; (b) Compressive strength growth rate

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图 3 不同GQDs掺量对蛇纹石混凝土劈裂抗拉强度的影响

Figure 3. Splitting tensile strength of serpentine concrete with different dosage of GQDs

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图 4 蛇纹石混凝土的结晶水损失率

Figure 4. Crystal water loss rate of serpentine concrete

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图 5 高温后蛇纹石混凝土的抗压强度

Figure 5. Compressive strength of serpentine concrete exposed to high temperatures

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图 6 高温后蛇纹石混凝土的劈裂抗拉强度

Figure 6. Splitting tensile strength of serpentine concrete exposed to high temperatures

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图 7 高温后SG-12的XRD图谱

Figure 7. XRD patterns of SG-12 at elevated temperatures

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图 8 高温后SG-12的SEM图像

Figure 8. SEM images of SG-12 at elevated temperature

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表 1 水泥和蛇纹石的化学成分

Table 1. Chemical compositions of cement and serpentine

Material type	Mass fraction/wt%
Material type	MgO	SiO₂	Fe₂O₃	Al₂O₃	CaO	Na₂O	SO₃	Other	LOI
Cement	2.16	21.45	4.37	5.07	60.65	0.58	2.33	1.25	2.14
Serpentine	42.43	37.56	4.22	0.56	0.32	0.17	0.11	0.79	13.84

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表 2 蛇纹石的物理性质

Table 2. Physical properties of serpentine

Aggregate type	Apparent density/ (kg·m⁻³)	Bulk density/ (kg·m⁻³)	Voidage/wt%	Water absorption/wt%	Moisture content/wt%	Crush index/wt%	Fineness modulus
Fine serpentine	2 320	1 330	43	9.6	5.0	28.0	2.7
Coarse serpentine	2 600	1 490	43	2.8	1.3	11.7	—

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表 3 蛇纹石混凝土配合比/(kg·m⁻³)

Table 3. Mix proportion of serpentine concrete/(kg·m⁻³)

Concrete type	Cement	Coarse serpentine	Fine serpentine	Water	GQDs
SG-0	375	1 039	637	195	0
SG-03	375	1 039	637	195	0.112 5
SG-06	375	1 039	637	195	0.225 0
SG-09	375	1 039	637	195	0.337 5
SG-12	375	1 039	637	195	0.450 0

下载: 导出CSV

[1]	ZARITSKIY S M, EGOROV A L, KABAKCHI S A, et al. Evaluation of the water radiolysis in the serpentinite concrete of the VVER-1200 reactor shielding[J]. Physics of Atomic Nuclei, 2022, 85(8): 1411-1417. doi: 10.1134/S1063778822080154
[2]	石建军, 许新春, 张志恒, 等. 不同产地防中子辐射蛇纹石骨料混凝土比选[J]. 硅酸盐通报, 2023, 42(4): 1282-1290. SHI Jianjun, XU Xinchun, ZHANG Zhiheng, et al, Comparison and selection of anti-neutron radiation concrete with serpentine aggregate from different producing areas[J]. Bulletin of the Chinese Ceramic Society, 2023, 42(4): 1282-1290 (in Chinese).
[3]	MESBAHI A, AZARPEYVAND A A, SHIRAZI A. Photoneutron production and backscattering in high density concretes used for radiation therapy shielding[J]. Annals of Nuclear Energy, 2011, 38(12): 2752-2756. doi: 10.1016/j.anucene.2011.08.023
[4]	ABREFAH R G, BIRIKORANG S A, NYARKO B J B, et al. Design of serpentine cask for Ghana research reactor-1 spent nuclear fuel[J]. Progress in Nuclear Energy, 2014, 77: 84-91. doi: 10.1016/j.pnucene.2014.06.011
[5]	OUDA A S. Development of high-performance heavy density concrete using different aggregates for gamma-ray shielding[J]. Progress in Nuclear Energy, 2015, 79: 48-55. doi: 10.1016/j.pnucene.2014.11.009
[6]	CHEN F J, GAO C C, JIN L, et al. Dynamic responses of radiation-induced heavyweight concrete subjected to biaxial compression[J]. International Journal of Mechanical Sciences, 2023, 257: 108519. doi: 10.1016/j.ijmecsci.2023.108519
[7]	AHMED R, SAAD HASSAN G, SCOTT T, et al. Assessment of five concrete types as candidate shielding materials for a compact radiation source based on the IECF[J]. Materials, 2023, 16(7): 2845. doi: 10.3390/ma16072845
[8]	TEKIN I, KOTAN T, YURDAKUL M, et al. Mechanical properties of conventional concrete produced with different type of aggregates in Bayburt region[J]. Journal of Polytechnic-Politeknik Dergisi, 2017, 20(3): 513-518.
[9]	MASOUD M A, EL-KHAYATT A M, MAHMOUD K A, et al. Valorization of hazardous chrysotile by H₃BO₃ incorporation to produce an innovative eco-friendly radiation shielding concrete: implications on physico-mechanical, hydration, microstructural, and shielding properties[J]. Cement and Concrete Composites, 2023, 141: 105120. doi: 10.1016/j.cemconcomp.2023.105120
[10]	王开华, 钱伏华. 蛇纹石混凝土在田湾核电站的实验与应用[J]. 中国核电, 2015, 8(1): 38-41. WANG Kaihua, QIAN Fuhua. Serpentine concrete in the experiment and application of tianwan nuclear power station[J]. China Nuclear Power, 2015, 8(1): 38-41 (in Chinese).
[11]	伍崇明. 核工程抗强辐射屏蔽混凝土试验研究[D]. 长沙: 中南大学, 2008. WU Chongming, The study on strong radiation shielding concrete test of nuclear engineering[D]. Changsha: Central South University, 2008 (in Chinese).
[12]	SAYYADI A, MOHAMMADI Y, ADLPARVAR M R. Mechanical, durability, and gamma ray shielding characteristics of heavyweight concrete containing serpentine aggregates and lead waste slag[J]. Advances in Civil Engineering, 2023, 2023: 1-11.
[13]	PAUL M B, ANKAN A D, DEB H, et al. A Monte Carlo simulation model to determine the effective concrete materials for fast neutron shielding[J]. Radiation Physics and Chemistry, 2023, 202: 110476. doi: 10.1016/j.radphyschem.2022.110476
[14]	ZAYED A M, MASOUD M A, RASHAD A M, et al. Influence of heavyweight aggregates on the physico-mechanical and radiation attenuation properties of serpentine-based concrete[J]. Construction and Building Materials 2020, 260: 120473.
[15]	LIU C J, HUNAG X C, WU Y Y, et al. Studies on mechanical properties and durability of steel fiber reinforced concrete incorporating graphene oxide[J]. Cement and Concrete Composites, 2022, 130: 104508. doi: 10.1016/j.cemconcomp.2022.104508
[16]	FONSEKA I, MOHOTTI D, WIJESOORIYA K, et al. Influence of graphene oxide on abrasion resistance and strength of concrete[J]. Construction and Building Materials, 2023, 404: 133280. doi: 10.1016/j.conbuildmat.2023.133280
[17]	LU D, WANG D Y, WANG Y, et al. Nano-engineering the interfacial transition zone between recycled concrete aggregates and fresh paste with graphene oxide[J]. Construction and Building Materials, 2023, 384: 131244. doi: 10.1016/j.conbuildmat.2023.131244
[18]	褚洪岩, 高李, 秦健健, 等. 磺化石墨烯对再生砂超高性能混凝土力学性能和耐久性能的影响[J]. 材料导报, 2022, 36(5): 95-99. CHU Hongyan, GAO Li, QIN Jianjian, et al. Effects of graphene sulfonate nanosheets on mechanical properties and durability of ultra-high performance concrete produced by recycled sand[J]. Materials Reports, 2022, 36(5): 95-99 (in Chinese).
[19]	郑慧君. 石墨质改性混凝土高温性能的研究[J]. 硅酸盐通报, 2020, 39(12): 3851-3857. ZHENG Huijun. High Temperature Performance of Graphite Modified Concrete[J]. Bulletin of the Chinese Ceramic Society, 2020, 39(12): 3851-3857 (in Chinese).
[20]	MOHAMMED A, SANJAYAN J G, NAZARI A, et al. Effects of graphene oxide in enhancing the performance of concrete exposed to high-temperature[J]. Australian Journal of Civil Engineering, 2017, 15(1): 61-71. doi: 10.1080/14488353.2017.1372849
[21]	CHU H, JIANG J, SUN W, et al. Mechanical and thermal properties of graphene sulfonate nanosheet reinforced sacrificial concrete at elevated temperatures[J]. Construction and Building Materials, 2017, 153: 682-694. doi: 10.1016/j.conbuildmat.2017.07.157
[22]	IQBAL H W, KHUSHNOOD R A, BALOCH W L, et al. Influence of graphite nano/micro platelets on the residual performance of high strength concrete exposed to elevated temperature[J]. Construction and Building Materials, 2020, 253: 119029. doi: 10.1016/j.conbuildmat.2020.119029
[23]	BAŞGÖZ Ö, GÜLER S H, GÜLER Ö, et al. Synergistic effect of boron nitride and graphene nanosheets on behavioural attitudes of polyester matrix: Synthesis, experimental and Monte Carlo simulation studies[J]. Diamond and Related Materials, 2022, 126: 109095. doi: 10.1016/j.diamond.2022.109095
[24]	张文博, 李莉, 李思纯, 等. 石墨烯量子点的改性及应用[J]. 复合材料学报, 2022, 39(7): 3104-3120. ZHANG Wenbo, LI Li, LI Sichun, et al. Modification and application of graphene quantum dots[J]. Acta Materiae Compositae Sinica, 2022, 39(7): 3104-3120 (in Chinese).
[25]	LONG W J, XU P, YU Y, et al. Scalable preparation of high-dispersion g-C₃N₄ via GQDs-assisted ultrasonic exfoliation for accelerating cement hydration[J]. Cement and Concrete Composites, 2022, 134: 104782. doi: 10.1016/j.cemconcomp.2022.104782
[26]	LONG W J, LIU J W, HE C. A facile approach to disperse metakaolin for promoting compressive strength of cement composites[J]. Construction and Building Materials, 2023, 404: 133268. doi: 10.1016/j.conbuildmat.2023.133268
[27]	He H J, Shuang E, Wen T D, et al. Employing novel N-doped graphene quantum dots to improve chloride binding of cement[J]. Construction and Building Materials, 2023, 401: 132944. doi: 10.1016/j.conbuildmat.2023.132944
[28]	LU L Q, ZHANG Y, YIN B. Structure evolution of the interface between graphene oxide-reinforced calcium silicate hydrate gel particles exposed to high temperature[J]. Computational Materials Science, 2020, 173: 109440. doi: 10.1016/j.commatsci.2019.109440
[29]	国家能源局. 核电厂屏蔽混凝土配合比设计规程: NB/T 20378-2016[S]. 北京: 核工业标准化研究所, 2016. National Energy Administration. Design Specification for Mix Design of Shielding Concrete Used in Nuclear Power Plant: NB/T 20378-2016[S]. Beijing: Nuclear Industry Standardization Research Institute, 2016 (in Chinese).
[30]	中华人民共和国住房和城乡建设部. 混凝土物理力学性能试验方法标准: GB/T 50081-2019[S]. 北京: 中国建筑工业出版社, 2019. Ministry of Housing and Urban-Rural Development of the People’s Republic of China. Standard for test methods of concrete physical and mechanical properties: GB/T 50081-2019[S]. Beijing: China Architecture & Building Press, 2019 (in Chinese).
[31]	CUI K, CHANG J. Hydration, reinforcing mechanism, and macro performance of multi-layer graphene-modified cement composites[J]. Journal of Building Engineering, 2022, 57: 104880. doi: 10.1016/j.jobe.2022.104880
[32]	吴磊, 吕生华, 李泽雄, 等. 超低掺量氧化石墨烯的分散行为及其对水泥基材料结构与性能的影响[J]. 复合材料学报, 2023, 40(4): 2296-2307. WU Lei, LV Shenghua, LI Zexiong, et al. Dispersion behavior of ultra-low dosage graphene oxide and its effect on structure and performances of cement-based materials[J]. Acta Materiae Compositae Sinica, 2023, 40(4): 2296-2307 (in Chinese).
[33]	LIN C Q, WEI W, HU Y H. Catalytic behavior of graphene oxide for cement hydration process[J]. Journal of Physics and Chemistry of Solids, 2016, 89: 128-133. doi: 10.1016/j.jpcs.2015.11.002
[34]	芦永红, 吴瑞, 周泉竹, 等. 石墨烯量子点在化学溶剂中的分散性能研究[J]. 化工新型材料, 2018, 46(6): 202-205+209. LU Yonghong, WU Rui, ZHOU Quanzhu, et al. Dispersion behavior of graphene quantum dots in chemical solvent[J]. New Chemical Materials, 2018, 46(6): 202-205+209 (in Chinese).
[35]	LV S H, MA Y J, QIU C C, et al. Effect of graphene oxide nanosheets of microstructure and mechanical properties of cement composites[J]. Construction and Building Materials, 2013, 49: 121-127. doi: 10.1016/j.conbuildmat.2013.08.022
[36]	CHEN Y, LI X Y, DONG B Q, et al. High-temperature properties of cement paste with graphene oxide agglomerates[J]. Construction and Building Materials, 2022, 320: 126286. doi: 10.1016/j.conbuildmat.2021.126286
[37]	朋改非, 牛旭婧, 成铠. 超高性能混凝土的火灾高温性能研究综述[J]. 材料导报, 2017, 31(23): 17-23. doi: 10.11896/j.issn.1005-023X.2017.023.002 PENG Gaifei, NIU Xujing, CHENG Kai. Research on fire resistance of ultra-high-performance concrete: a review[J]. Materials Reports, 2017, 31(23): 17-23 (in Chinese). doi: 10.11896/j.issn.1005-023X.2017.023.002
[38]	LI G, ZHANG L W. Microstructure and phase transformation of graphene-cement composites under high temperature[J]. Composites Part B:Engineering, 2019, 166: 86-94. doi: 10.1016/j.compositesb.2018.11.127
[39]	章钰桢, 姜兆霞, 李三忠, 等. 大洋橄榄岩的蛇纹石化过程: 从海底水化到俯冲脱水[J]. 岩石学报, 2022, 38(4): 1063-1080. doi: 10.18654/1000-0569/2022.04.07 ZHANG Yuzhen, JIANG Zhaoxia, LI Sanzhong, et al. The process of oceanic peridotite serpentinization: from seafloor hydration to subduction dehydration[J]. Acta Petrologica Sinica, 2022, 38(4): 1063-1080 (in Chinese). doi: 10.18654/1000-0569/2022.04.07
[40]	MASOUD M A, RASHAD A M, SAKR K, et al. Possibility of using different types of Egyptian serpentine as fine and coarse aggregates for concrete production[J]. Materials and Structures, 2020, 53(4): 1-17.