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Bulletin of Engineering Geology and the Environment

Erschienen in:

14.04.2021 | Original Paper

Improvement of characteristics and freeze-thaw durability of solidified loess based on microbially induced carbonate precipitation

verfasst von: Xiaohao Sun, Linchang Miao, Hengxing Wang, Runfa Chen, Xin Guo

Erschienen in: Bulletin of Engineering Geology and the Environment | Ausgabe 6/2021

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Abstract

Bio-cementation is currently applied to solidify sandy soils, but only few studies use it to cement loess soil particles. In this study, the microbially induced carbonate precipitation (MICP) method was used to solidify loess soils. In addition, loess is widely distributed in the regions of northwest of China, where repeated seasonal freeze-thaw results in the structural damages in loess. Therefore, the freeze-thaw cycle test was conducted to study the durability of bio-treated loess soils. Results showed that the permeability coefficients of all samples decreased during the solidification, but the change pattern varied greatly because of different densities. Calcium carbonate (CaCO₃) in samples with smaller densities distributed relatively uniformly. After solidification, the content of large aggregates and small pores increased, and the content of small aggregates and large pores decreased. For samples with a density of 1.5 g/cm³, the content of large aggregates was the largest and the content of small aggregates was the smallest. Moreover, compared with untreated samples, increasing freeze-thaw cycles resulted in a larger increase in sonic time values of treated samples, but their mass and strengths significantly decreased. The increase in freeze-thaw cycles decreased the difference between sonic time values in solidified samples, while porosity and contents of large pores increased regardless of density. Overall, after bio-cementation, the solidified samples with a density of 1.5 g/cm³ had better aggregate effect and resistance for freeze-thaw cycles, and a uniform solidification effect, which present promising potential for application of MICP in the field.

Vorheriger Artikel Experimental study on the coupled behavior of dynamic cracking and moisture-heat evolution of a clay under evaporation

Nächster Artikel Biochar-assisted bio-cementation of a sand using native bacteria

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Al Qabany A, Soga K (2013) Effect of chemical treatment used in MICP on engineering properties of cemented soils. Geotechnique 63:331–339CrossRef

Atashgahi S, Tabarsa A, Shahryari A, Hosseini S (2020) Effect of carbonate precipitating bacteria on strength and hydraulic characteristics of loess soil. Bull Eng Geol Environ

Cheng L, Shahin M, Chu J (2019) Soil bio-cementation using a new one-phase low-ph injection method. Acta Geotech 14(3):615–626CrossRef

DeJong J, Fritzges M, Nusslein K (2006) Microbially induced cementation to control sand response to undrained shear. J Geotech Geoenviron Eng 132:1381–1392CrossRef

Dejong J, Soga K, Banwart S et al (2011) Soil engineering in vivo: harnessing natural biogeochemical systems for sustainable, multi-functional engineering solutions. J R Soc Interface 8(54):1–15CrossRef

Derbyshire E, Meng X, Dijkstra T (2000) Landslides in the thick loess terrain of North-West China. John Wiley and Sons Ltd, London

De Muynck W, Debrouwer D, De Belie N et al (2008) Bacterial carbonate precipitation improves the durability of cementitious materials. Cem Concr Res 38(7):1005–1014CrossRef

Harkes M, Van Paassen L, Booster J, Whiffin V, van Loosdrecht M (2010) Fixation and distribution of bacterial activity in sand to induce carbonate precipitation for ground reinforcement. Ecol Eng 36(2):112–117CrossRef

Hommel J, Lauchnor E, Phillips A, Gerlach R, Cunningham A, Helmig R et al (2015) A revised model for microbially induced calcite precipitation: improvements and new insights based on recent experiments. Water Resour Res 51(5):3695–3715CrossRef

Gowthaman S, Nakashima K, Kawasaki S (2020) Freeze-thaw durability and shear responses of cemented slope soil treated by microbial induced carbonate precipitation. Soils Found 60(4):840–855CrossRef

Ji J, Li H, Yan G (2008) Effect of temperature on ultrasonic wave velocity in concrete. J Build Mater 11(3):349–352 (in Chinese)

Juang C, Dijkstra T, Wasowski J, Meng X (2019) Loess geohazards research in China: advances and challenges for mega engineering projects. Eng Geol 251:1–10CrossRef

Leng Y, Peng J, Wang Q, Meng Z, Huang W (2018) A fluidized landslide occurred in the Loess Plateau: a study on loess landslide in South Jingyang Tableland. Eng Geol 236:129–136CrossRef

Li Q, Dong L, Li X, Yin Z, Liu X (2011) Effects of sonic speed on location accuracy of acoustic emission source in rocks. Trans Nonferrous Metals Soc China 21(12):2719–2726CrossRef

Liu Z, Liu F, Ma F, Wang M, Bai X, Zheng Y, Yin H, Zhang G (2016) Collapsibility, composition, and microstructure of loess in China. Can Geotech J 53(4):673–686CrossRef

Mahawish A, Bouazza A, Gates W (2018) Effect of particle size distribution on the bio-cementation of coarse aggregates. Acta Geotech 13(4):1019–1025CrossRef

Miao L, Wu L, Sun X, Li X, Zhang J (2020) Method of solidifying desert sands with enzyme-catalysed mineralization. Land Degrad Dev 31(11):1317–1324CrossRef

Mitchell A, Phillips A, Kaszuba J et al (2008) Microbially enhanced carbonate mineralization and the geologic containment of CO₂. Geochim Cosmochim Acta 72(12):636–636

Mitchell J, Santamarina C (2005) Biological considerations in geotechnical engineering. J Geotech Geoenviron 131(10):1222–1233CrossRef

Paassen L (2009) Biogrout ground improvement by microbially induced carbonate precipitation, PhD thesis. Delft University of Technology, Netherlands

Paassen L, Ghose R, Linden T et al (2010) Quantifying bio-mediated ground improvement by ureolysis: a large scale biogrout experiment. J Geotech Geoenviron Eng 136(12):1721–1728CrossRef

Peng D, Xu Q, Liu F, He Y, Zhang S, Qi X, Zhao K, Zhang X (2018) Distribution and failure modes of the landslides in Heitai terrace. China Eng Geol 236:97–110CrossRef

Salifu E, Maclachlan E, Iyer K et al (2015) Application of microbially induced calcite precipitation in erosion mitigation and stabilisation of sandy soil foreshore slopes: a preliminary investigation. Eng Geol 201(4):96–105

Smalley I (1995) Making the material: the formation of silt sized primary mineral particles for loess deposits. Quat Sci Rev 14(7–8):645–651CrossRef

Stocks-Fischer S, Galinat J, Bang S (1999) Microbiological precipitation of CaCO₃. Soil Biol Biochem 31(11):1563–1571CrossRef

Sun X, Miao L, Tong T, Wang C (2018a) Study of the effect of temperature on microbially induced carbonate precipitation. Acta Geotech 14(3):627–638CrossRef

Sun X, Miao L, Tong T, Wang C (2018b) Improvement of microbial-induced calcium carbonate precipitation technology for sand solidification. J Mater Civ Eng 30(11):04018301CrossRef

Sun X, Miao L, Wang C (2019a) Glucose addition improves the bio-remediation efficiency for crack repair. Mater Struct 52(6):111CrossRef

Sun X, Miao L, Wu L, Chen R (2019b) The improvement of bio-cementation at low temperature based on Bacillus megaterium. Appl Microbiol Biotechnol 103(17):7191–7202CrossRef

Sun X, Miao L, Chen R (2019c) Effects of different clay's percentages on improvement of sand-clay mixtures with microbially induced calcite precipitation. Geomicrobiol J 1-9

Sun X, Miao L, Wu L (2020a) Applicability and theoretical calculation of enzymatic calcium carbonate precipitation for sand improvement. Geomicrobiol J:1–11

Sun X, Miao L, Chen R (2020b) The application of bio-cementation for improvement of collapsibility of loess. Int J Environ Sci Technol:1–9

Sun X, Miao L, Yuan J, Wang H, Wu L (2020c) Application of enzymatic calcification for dust control and rainfall erosion resistance improvement. Sci Total Environ

Sun X, Miao L, Wu L, Wang H (2021a) Theoretical quantification for cracks repair based on microbially induced carbonate precipitation (micp) method. Cem Concr Compos 1:103950CrossRef

Sun X, Miao L, Wang H, Yin W, Wu L (2021b) Mineralization crust field experiment for desert sand solidification based on enzymatic calcification. J Environ Manag 287:112315CrossRef

Terzis D, Bernier-Latmani R, Laloui L (2016) Fabric characteristics and mechanical response of bio-improved sand to various treatment conditions. Geotech Lett 6(1)

Trofimov V, Balykova S, Andreeva T, Ershova A (2015) Subsidence of buried soils in cyclic loess sequences of the northern Eurasia. In: Engineering Geology for Society and Territory-Volume 5. Springer, Cham, pp 439–442CrossRef

Whiffin V (2004) Microbial CaCO3 precipitation for the production of biocement. Murdoch University, Perth

Whiffin V, van Paassen L, Harkes M (2007) Microbial carbonate precipitation as a soil improvement technique. Geomicrobiol J 24(5):417–423CrossRef

Wu X (2003) Technical hand book for nondestructive testing of concrete. China Communications Press, Beijing

Xu L, Dai F, Tu X, Tham L, Zhou Y, Iqbal J (2014) Landslides in a loess platform, North-West China. Landslides 11(6):993–1005CrossRef

Xu S, Wu Z, Zhao W, Zhao T (2017) Study of the microscopic pores of structured loess based on Matlab and IPP. China Earthquake Eng J 39(1):80–87 (in Chinese)

Zamani A, Montoya B (2016) Permeability reduction due to microbial induced calcite precipitation in sand. Geo-Chicago:94–103

Zhao J, Wang P, Li Z (2011) Subsoil disposal of expressway in damp loess area. Road Machin Constr Mechan 28(9):43–45

Zhou L, Hou X, Wang Z (2014) The effect of the freeze-thaw cycles in nanometer pores on the cement structure. Appl Mech Mater 488-489:620–624CrossRef

Titel: Improvement of characteristics and freeze-thaw durability of solidified loess based on microbially induced carbonate precipitation
verfasst von: Xiaohao Sun
Linchang Miao
Hengxing Wang
Runfa Chen
Xin Guo
Publikationsdatum: 14.04.2021
Verlag: Springer Berlin Heidelberg
Erschienen in: Bulletin of Engineering Geology and the Environment / Ausgabe 6/2021
Print ISSN: 1435-9529
Elektronische ISSN: 1435-9537
DOI: https://doi.org/10.1007/s10064-021-02241-2

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