Effect of sodium sulfate on strength and microstructure of alkali-activated fly ash based geopolymer

Qing-feng Lv; Zi-shuai Wang; Liu-yang Gu; Yi Chen; Xiao-kang Shan

doi:10.1007/s11771-020-4400-4

Journal of Central South University ›› 2020, Vol. 27 ›› Issue (6) : 1691 -1702. DOI: 10.1007/s11771-020-4400-4

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Effect of sodium sulfate on strength and microstructure of alkali-activated fly ash based geopolymer

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Abstract

The main objective of this paper focuses on the changes that occur in the strength and microstructural properties of sodium silicate activated fly ash based geopolymer due to varying the sulfate salt and water content. A series of tests including X-ray diffraction, Fourier transform infrared spectroscopy, scanning electron microscopy, physical adsorption and unconfined compressive strength were used to investigate this effect. The results indicate that the higher water content has an adverse effect on the alkali activation and microstructural properties of geopolymer, so the optimum mass ratio of sodium sulfate in alkali-activated geopolymer under different water-to-binder ratios shows a “peak shifting” phenomenon, i.e., the higher the water-to-binder ratio, the higher the optimum mass ratio. Lower presence of sodium sulfate has no significant effect on the alkali-activated geopolymer systems; higher addition of sodium sulfate, however, could cause the symmetrical stretching vibration of Si-O and the symmetrical stretching vibration of Si-O-Si and Al-O-Si, and promote the formation of N-A-S-H gels. Furthermore, the cement effect of the gel and sodium sulfate aggregate could improve the integrity of pore structure obviously. The maximum strength of geopolymer curing at ambient temperature was 52 MPa. This study obtains the rule that the strength properties of alkali-activated geopolymers vary with the water-to-binder ratio and sodium sulfate content. The feasibility of geopolymer co-activated by sodium sulfate and sodium silicate was investigated, and reference for engineering application of alkali-activated geopolymer in salt-bearing areas was provided.

Keywords

geopolymer / microstructure / fly ash / sodium sulfate / water-to-binder ratio

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Qing-feng Lv, Zi-shuai Wang, Liu-yang Gu, Yi Chen, Xiao-kang Shan. Effect of sodium sulfate on strength and microstructure of alkali-activated fly ash based geopolymer. Journal of Central South University, 2020, 27(6): 1691-1702 DOI:10.1007/s11771-020-4400-4

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	KoleżyńskiA, KrólM, ŻychowiczM. The structure of geopolymers-Theoretical studies [J]. Journal of Molecular Structure, 2018, 1163: 465-471

[2]	FanF-h, LiuZ, XuG-j, PengH, CaiC S. Mechanical and thermal properties of fly ash based geopolymers [J]. Construction and Building Materials, 2018, 160: 66-81

[3]	NathS K, MaitraS, MukherjeeS. Microstructural and morphological evolution of fly ash based geopolymers [J]. Construction and Building Materials, 2016, 111: 758-765

[4]	PeyneJ, JousseinE, GautronJ, DoudeauJ, RossignolS. Feasibility of producing geopolymer binder based on a brick clay mixture [J]. Ceramics International, 2017, 43: 9860-9871

[5]	NmiriA, DucM, HamdiN, MarzoukO Y, SrasraE. Replacement of alkali silicate solution with silica fume in metakaolin-based geopolymers [J]. International Journal of Minerals Metallurgy and Materials, 2019, 26(5): 555-564

[6]	GhoshP, KumarH, BiswasK. Fly ash and kaolinite-based geopolymers: Processing and assessment of some geotechnical properties [J]. International Journal of Geotechnical Engineering, 2016, 10(4): 1-10

[7]	ChenX, ZhuG-r, ZhouM-k, WangJ, ChenQ. Effect of organic polymers on the properties of slag-based geopolymers [J]. Construction and Building Materials, 2018, 167: 216-224

[8]	ProvisJ L. Alkali-activated materials [J]. Cement and Concrete Research, 2018, 114: 40-48

[9]	ProvisJ L, BernalS A. Geopolymers and related alkali-activated materials [J]. Annual Review of Materials Research, 2014, 44(1): 299-327

[10]	AbabnehF A, AlakhrasA I, HeikalM, IbrahimS M. Stabilization of lead bearing sludge by utilization in fly ash-slag based geopolymer [J]. Construction and Building Materials, 2019, 227: 116694

[11]	HeikalM, NassarM Y, El-SayedG, IbrahimS M. Physico-chemical, mechanical, microstructure and durability characteristics of alkali activated Egyptian slag [J]. Construction and Building Materials, 2014, 6960-72

[12]	OderjiS Y, ChenB, AhmadM R, ShahS F A. Fresh and hardened properties of one-part fly ash-based geopolymer binders cured at room temperature: Effect of slag and alkali activators [J]. Journal of Cleaner Production, 2019, 225: 1-10

[13]	AhnJ, KimW S, UmW. Development of metakaolin-based geopolymer for solidification of sulfate-rich HyBRID sludge waste [J]. Journal of Nuclear Materials, 2019, 518: 247-255

[14]	PrasittisopinL, SereewatthanawutI. Effects of seeding nucleation agent on geopolymerization process of fly-ash geopolymer [J]. Frontiers of Structural and Civil Engineering, 2018, 12: 16-25

[15]	ChequerD L, FrizonF. Impact of sulfate and nitrate incorporation on potassium- and sodium-based geopolymers: Geopolymerization and materials properties [J]. Journal of Materials Science, 2011, 46(17): 5657-5664

[16]	KomnitsasK, ZaharakiD, BartzasG. Effect of sulphate and nitrate anions on heavy metal immobilisation in ferronickel slag geopolymers [J]. Applied Clay Science, 2013, 73: 103-109

[17]	CriadoM, FernandezJ A, PalomoA. Effect of sodium sulfate on the alkali activation of fly ash [J]. Cement and Concrete Composites, 2010, 32: 589-594

[18]	IsmailI, BernalS A, ProvisJ L, HandanS, van DeventerJ S J. Microstructural changes in alkali activated fly ash/slag geopolymers with sulfate exposure [J]. Materials and Structures, 2013, 46: 361-373

[19]	ZhangY-j, ChaiQ, YangM-y, FanB-w, LiX. Synthesis of bottom ash-based geopolymer co-activated by double salts [J]. Journal of Functional Materials, 2016, 47(9): 9176-9181(in Chinese)

[20]	CuiY, WangD-m, WangY-r, SunR, RuiY-f. Effects of the n(H₂O: Na₂O_eq) ratio on the geopolymerization process and microstructures of fly ash-based geopolymers [J]. Journal of Non-Crystalline Solids, 2019, 511: 19-28

[21]	DuxsonP, Fernández-JiménezA, ProvisJ L, LukeyG C, PalomoA, van DeventerJ S J. Geopolymer technology: The current state of the art [J]. Journal of Materials Science, 2007, 42(9): 2917-2933

[22]	KumarS, KristalyF, MucsiG. Geopolymerisation behaviour of size fractioned fly ash [J]. Advanced Powder Technology, 2015, 26(1): 24-30

[23]	LiX-b, YeJ-j, LiuZ-h, QiuY-q, LiL-j, MaoS, WangX-c, ZhangQ. Microwave digestion and alkali fusion assisted hydrothermal synthesis of zeolite from coal fly ash for enhanced adsorption of Cd(II) in aqueous solution [J]. Journal of Central South University, 2018, 25(1): 9-20

[24]	LvQ-f, JiangL-s, MaB, ZhaoB-h, HuoZ-s. A study on the effect of the salt content on the solidification of sulfate saline soil solidified with an alkali-activated geopolymer [J]. Construction and Building Materials, 2018, 176: 68-74

[25]	PeyneJ, JousseinE, GautronJ, DoudeauJ, RossignolS. Feasibility of producing geopolymer binder based on a brick clay mixture [J]. Ceramics International, 2017, 43(13): 9860-9871

[26]	KrolM, RozekP, ChlebdaD, MozgawaW. Influence of alkali metal cations/type of activator on the structure of alkali-activated fly ash-ATR-FTIR studies [J]. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2018, 198: 33-37

[27]	RakhimovaN R, RakhimovR Z, MorozovV P, GaifullinA R, PotapovaL I, GubaidullinaA M, OsinY N. Marl-based geopolymers incorporated with limestone: A feasibility study [J]. Journal of Non-Crystalline Solids, 2018, 492: 1-10

[28]	KottaA B, KarakS K, KumarM. Chemical, physical, thermal, textural and mineralogical studies of natural iron ores from Odisha and Chhattisgarh regions, India [J]. Journal of Central South University, 2018, 25(12): 2857-2870

[29]	HajimohammadiA, NgoT, KashaniA. Glass waste versus sand as aggregates: The characteristics of the evolving geopolymer binders [J]. Journal of Cleaner Production, 2018, 193: 593-603

[30]	LeeW K W, van DeventerJ S J. The effects of inorganic salt contamination on the strength and durability of Geopolymers [J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2002, 211: 115-126

[31]	LvQ-f, JiaM-x, WangS-x, ZhouG, WangQ-d. Effect of salt content on compressive strength of solidified sulphate saline soil [J]. Journal of Central South University: Science and Technology, 2018, 49(3): 718-724(in Chinese)

[32]	LiQ, XuH, LiF-h, ShenL-f, ZhaiJ-p. Synthesis of geopolymer composites from blends of CFBC fly and bottom ashes [J]. Fuel, 2012, 97: 366-372

[33]	MajidiB. Geopolymer technology, from fundamentals to advanced applications: A review [J]. Materials Technology, 2009, 24(2): 79-87

[34]	HajimohammadiA, van DeventerJ S J. Characterisation of one-part geopolymer binders made from fly ash [J]. Waste and Biomass Valorization, 2017, 8(1): 225-233

[35]	LeongH Y, OngD E L, SanjayanJ G, NazariA. The effect of different Na2O and K2O ratios of alkali activator on compressive strength of fly ash based-geopolymer [J]. Construction and Building Materials, 2016, 106: 500-511