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THE EFFECTS OF DIFFERENT SOURCES OF CALCIUM IN IMPROVEMENT OF SOILS BY MICROBIALLY INDUCED CALCITE PRECIPITATION (MICP)

Yıl 2019, Cilt: 37 Sayı: 3, 953 - 965, 01.09.2020

Öz

Several soil improvement techniques are successfully implemented today. Studies are increasingly becoming popular on microbially induced calcite precipitation (MICP) as an environment-friendly and sustainable method that is an alternative to other soil improvement techniques. Our study examined the effects of different sources of calcium on an improvement that was carried out on a sand soil with a 35% relative density by using the MICP method. The results were analyzed by using unconfined compression, permeability, calcite formation percentage, pH, SEM (scanning electron microscopy) and XRD (x-ray diffraction) experiments. As a result of the unconfined compression test, the strength values were obtained as 2406 kPa in the specimens where calcium chloride was used as a calcium source, 2435 kPa in the specimens where calcium nitrate was used and 64 kPa in the specimens where calcium acetate was used. The permeability experiment revealed a decrease in permeability of 80.8% for calcium chloride, 23% for calcium nitrate and 90.4% for calcium acetate. According to the results of the SEM analyses, the structures that formed in all specimens bound the grains to each other and coated the surfaces of the grains. In the XRD analyses, calcite formation was observed in the specimens where calcium chloride and calcium nitrate were used as the source, while, in contrast, vaterite formations were also observed in the specimens where calcium acetate was used as the source. It was determined that different sources of calcium had different effects on improvement of sand soils by microbially induced calcite precipitation (MICP).

Kaynakça

  • [1] Chu, J., Ivanov, V., He, J., Maeimi, M., & Wu, S., (2015) Use of biogeotechnologies for soil improvement. In Ground Improvement Case Histories (pp. 571-589). Butterworth-Heinemann..
  • [2] Dapples, E. C., (1942) The effect of macro-organisms upon near-shore marine sediments. Journal of Sedimentary Research, 12(3), 118-126.
  • [3] Rhoads, D. C., (1974) Organism-sediment relations on the muddy sea floor. Oceanography and Marine Biology, 12, 263-300.
  • [4] Mccall, P.L. & Tevesz, M.J.S. (Ed.), (1982) Animul Sediment Relations. The Biogenic Alteration of Sediments. Plenum Press, New York.
  • [5] Meadows, P. S., & Hariri, M. S. B., (1991) Effects of two infaunal polychaetes on sediment shear strength and permeability: an experimental approach. The Environmental Impact of Burrowing Animals and Animal Burrows, 63, 319-321.
  • [6] Ivanov, V., & Chu, J., (2008) Applications of microorganisms to geotechnical engineering for bioclogging and biocementation of soil in situ. Reviews in Environmental Science and Bio/Technology, 7(2), 139-153.
  • [7] Cheng, L., Cord-Ruwisch, R., & Shahin, M. A., (2013) Cementation of sand soil by microbially induced calcite precipitation at various degrees of saturation. Canadian Geotechnical Journal, 50(1), 81-90.
  • [8] Anbu, Periasamy, Chang-Ho Kang, Yu-Jin Shin, and Jae-Seong So., (2016) Formations of Calcium Carbonate Minerals by Bacteria and Its Multiple Applications. Springerplus, 5(1), 250.
  • [9] Bang, Sookie S., Johnna K. Galinat, and V. Ramakrishnan. (2001) Calcite Precipitation Induced by Polyurethane-Immobilized Bacillus Pasteurii. Enzyme and Microbial Technology, 28(4), 404–9.
  • [10] DeJong, J. T., Fritzges, M. B., & Nüsslein, K., (2006) Microbially induced cementation to control sand response to undrained shear. Journal of Geotechnical and Geoenvironmental Engineering, 132(11), 1381-1392.
  • [11] Li, S., (2013) A laboratory study of the effects of bio-stabilization on geomaterials. M.S. Thesis, Iowa State University, Ames, Iowa.
  • [12] Okwadha, G. D., & Li, J., (2010) Optimum conditions for microbial carbonate precipitation. Chemosphere, 81(9), 1143-1148.
  • [13] Ramachandran, S. K., Ramakrishnan, V., & Bang, S. S., (2001) Remediation of concrete using micro-organisms. ACI Materials Journal-American Concrete Institute, 98(1), 3-9.
  • [14] Stocks-Fischer, S., Galinat, J. K., & Bang, S. S., (1999) Microbiological precipitation of CaCO3. Soil Biology and Biochemistry, 31(11), 1563-1571.
  • [15] Whiffin, V. S., (2004) Microbial CaCO3 precipitation for the production of biocement. Doctoral dissertation, Murdoch University.
  • [16] Whiffin, V. S., van Paassen, L. A., & Harkes, M. P., (2007) Microbial carbonate precipitation as a soil improvement technique. Geomicrobiology Journal, 24(5), 417-423.
  • [17] De Muynck, W., Cox, K., De Belie, N., & Verstraete, W., (2008) Bacterial carbonate precipitation as an alternative surface treatment for concrete. Construction and Building Materials, 22(5), 875-885.
  • [18] Ariyanti, D., Handayani, N. A., & Hadiyanto, H., (2011) An overview of biocement production from microalgae. International Journal of Science and Engineering, 2(2), 31-33.
  • [19] Dick, J., De Windt, W., De Graef, B., Saveyn, H., Van der Meeren, P., De Belie, N., & Verstraete, W., (2006) Bio-deposition of a calcium carbonate layer on degraded limestone by Bacillus species. Biodegradation, 17(4), 357-367.
  • [20] Jiménez-López, C., Rodríguez-Navarro, C., Piñar, G., Carrillo-Rosúa, F. J., Rodriguez-Gallego, M., & Gonzalez-Muñoz, M. T., (2007) Consolidation of degraded ornamental porous limestone stone by calcium carbonate precipitation induced by the microbiota inhabiting the stone. Chemosphere, 68(10), 1929-1936.
  • [21] Jonkers, H. M., & Schlangen, E., (2008) Development of a bacteria-based self healing concrete. In Proc. int. FIB symposium (Vol. 1, pp. 425-430).
  • [22] Le Metayer-Levrel, G., Castanier, S., Orial, G., Loubiere, J. F., & Perthuisot, J. P., (1999) Applications of bacterial carbonatogenesis to the protection and regeneration of limestones in buildings and historic patrimony. Sedimentary geology, 126(1-4), 25-34.
  • [23] Rodriguez-Navarro, C., Rodriguez-Gallego, M., Chekroun, K. B., & Gonzalez-Munoz, M. T., (2003) Conservation of ornamental stone by Myxococcus xanthus-induced carbonate biomineralization. Appl. Environ. Microbiol., 69(4), 2182-2193.
  • [24] Tiano, P., Biagiotti, L., & Mastromei, G., (1999) Bacterial bio-mediated calcite precipitation for monumental stones conservation: methods of evaluation. Journal of microbiological methods, 36(1-2), 139-145.
  • [25] Tiano, P., Cantisani, E., Sutherland, I., & Paget, J. M., (2006) Biomediated reinforcement of weathered calcareous stones. Journal of Cultural Heritage, 7(1), 49-55.
  • [26] Tiano, P., (1995) Stone reinforcement by calcite crystal precipitation induced by organic matrix macromolecules. Studies in Conservation, 40(3), 171-176.
  • [27] Choi, S. G., Chu, J., Brown, R. C., Wang, K., & Wen, Z., (2017) Sustainable biocement production via microbially induced calcium carbonate precipitation: use of limestone and acetic acid derived from pyrolysis of lignocellulosic biomass. ACS Sustainable Chemistry & Engineering, 5(6), 5183-5190.
  • [28] Zhang, Y., Guo, H. X., & Cheng, X. H., (2015) Role of calcium sources in the strength and microstructure of microbial mortar. Construction and Building Materials, 77, 160-167.
  • [29] Li, Bing., (2015) Geotechnical Properties of Biocement Treated Sand and Clay. Doctoral Thesis, School of Civil and Environmental Engineering, Nanyang Technological University .
  • [30] Chu, J., Stabnikov, V., & Ivanov, V., (2012) Microbially induced calcium carbonate precipitation on surface or in the bulk of soil. Geomicrobiology Journal, 29(6), 544-549.
  • [31] Cheng, L., Shahin, M. A., & Mujah, D., (2016) Influence of key environmental conditions on microbially induced cementation for soil stabilization. Journal of Geotechnical and Geoenvironmental Engineering, 143(1), 04016083.
  • [32] Lee, M. L., Ng, W. S., & Tanaka, Y., (2013) Stress-deformation and compressibility responses of bio-mediated residual soils. Ecological engineering, 60, 142-149.
  • [33] Choi, S. G., Park, S. S., Wu, S., & Chu, J., (2017) Methods for calcium carbonate content measurement of biocemented soils. Journal of Materials in Civil Engineering, 29(11), 06017015.
  • [34] Cui, M. J., Zheng, J. J., Zhang, R. J., Lai, H. J., & Zhang, J., (2017) Influence of cementation level on the strength behaviour of bio-cemented sand. Acta Geotechnica, 12(5), 971-986.
  • [35] Moravej, S., Habibagahi, G., Nikooee, E., & Niazi, A., (2018) Stabilization of dispersive soils by means of biological calcite precipitation. Geoderma, 315, 130-137.
  • [36] Kalantary, F., & Kahani, M., (2015) Evaluation of the ability to control biological precipitation to improve sandy soils. Procedia Earth and Planetary Science, 15, 278-284.
Yıl 2019, Cilt: 37 Sayı: 3, 953 - 965, 01.09.2020

Öz

Kaynakça

  • [1] Chu, J., Ivanov, V., He, J., Maeimi, M., & Wu, S., (2015) Use of biogeotechnologies for soil improvement. In Ground Improvement Case Histories (pp. 571-589). Butterworth-Heinemann..
  • [2] Dapples, E. C., (1942) The effect of macro-organisms upon near-shore marine sediments. Journal of Sedimentary Research, 12(3), 118-126.
  • [3] Rhoads, D. C., (1974) Organism-sediment relations on the muddy sea floor. Oceanography and Marine Biology, 12, 263-300.
  • [4] Mccall, P.L. & Tevesz, M.J.S. (Ed.), (1982) Animul Sediment Relations. The Biogenic Alteration of Sediments. Plenum Press, New York.
  • [5] Meadows, P. S., & Hariri, M. S. B., (1991) Effects of two infaunal polychaetes on sediment shear strength and permeability: an experimental approach. The Environmental Impact of Burrowing Animals and Animal Burrows, 63, 319-321.
  • [6] Ivanov, V., & Chu, J., (2008) Applications of microorganisms to geotechnical engineering for bioclogging and biocementation of soil in situ. Reviews in Environmental Science and Bio/Technology, 7(2), 139-153.
  • [7] Cheng, L., Cord-Ruwisch, R., & Shahin, M. A., (2013) Cementation of sand soil by microbially induced calcite precipitation at various degrees of saturation. Canadian Geotechnical Journal, 50(1), 81-90.
  • [8] Anbu, Periasamy, Chang-Ho Kang, Yu-Jin Shin, and Jae-Seong So., (2016) Formations of Calcium Carbonate Minerals by Bacteria and Its Multiple Applications. Springerplus, 5(1), 250.
  • [9] Bang, Sookie S., Johnna K. Galinat, and V. Ramakrishnan. (2001) Calcite Precipitation Induced by Polyurethane-Immobilized Bacillus Pasteurii. Enzyme and Microbial Technology, 28(4), 404–9.
  • [10] DeJong, J. T., Fritzges, M. B., & Nüsslein, K., (2006) Microbially induced cementation to control sand response to undrained shear. Journal of Geotechnical and Geoenvironmental Engineering, 132(11), 1381-1392.
  • [11] Li, S., (2013) A laboratory study of the effects of bio-stabilization on geomaterials. M.S. Thesis, Iowa State University, Ames, Iowa.
  • [12] Okwadha, G. D., & Li, J., (2010) Optimum conditions for microbial carbonate precipitation. Chemosphere, 81(9), 1143-1148.
  • [13] Ramachandran, S. K., Ramakrishnan, V., & Bang, S. S., (2001) Remediation of concrete using micro-organisms. ACI Materials Journal-American Concrete Institute, 98(1), 3-9.
  • [14] Stocks-Fischer, S., Galinat, J. K., & Bang, S. S., (1999) Microbiological precipitation of CaCO3. Soil Biology and Biochemistry, 31(11), 1563-1571.
  • [15] Whiffin, V. S., (2004) Microbial CaCO3 precipitation for the production of biocement. Doctoral dissertation, Murdoch University.
  • [16] Whiffin, V. S., van Paassen, L. A., & Harkes, M. P., (2007) Microbial carbonate precipitation as a soil improvement technique. Geomicrobiology Journal, 24(5), 417-423.
  • [17] De Muynck, W., Cox, K., De Belie, N., & Verstraete, W., (2008) Bacterial carbonate precipitation as an alternative surface treatment for concrete. Construction and Building Materials, 22(5), 875-885.
  • [18] Ariyanti, D., Handayani, N. A., & Hadiyanto, H., (2011) An overview of biocement production from microalgae. International Journal of Science and Engineering, 2(2), 31-33.
  • [19] Dick, J., De Windt, W., De Graef, B., Saveyn, H., Van der Meeren, P., De Belie, N., & Verstraete, W., (2006) Bio-deposition of a calcium carbonate layer on degraded limestone by Bacillus species. Biodegradation, 17(4), 357-367.
  • [20] Jiménez-López, C., Rodríguez-Navarro, C., Piñar, G., Carrillo-Rosúa, F. J., Rodriguez-Gallego, M., & Gonzalez-Muñoz, M. T., (2007) Consolidation of degraded ornamental porous limestone stone by calcium carbonate precipitation induced by the microbiota inhabiting the stone. Chemosphere, 68(10), 1929-1936.
  • [21] Jonkers, H. M., & Schlangen, E., (2008) Development of a bacteria-based self healing concrete. In Proc. int. FIB symposium (Vol. 1, pp. 425-430).
  • [22] Le Metayer-Levrel, G., Castanier, S., Orial, G., Loubiere, J. F., & Perthuisot, J. P., (1999) Applications of bacterial carbonatogenesis to the protection and regeneration of limestones in buildings and historic patrimony. Sedimentary geology, 126(1-4), 25-34.
  • [23] Rodriguez-Navarro, C., Rodriguez-Gallego, M., Chekroun, K. B., & Gonzalez-Munoz, M. T., (2003) Conservation of ornamental stone by Myxococcus xanthus-induced carbonate biomineralization. Appl. Environ. Microbiol., 69(4), 2182-2193.
  • [24] Tiano, P., Biagiotti, L., & Mastromei, G., (1999) Bacterial bio-mediated calcite precipitation for monumental stones conservation: methods of evaluation. Journal of microbiological methods, 36(1-2), 139-145.
  • [25] Tiano, P., Cantisani, E., Sutherland, I., & Paget, J. M., (2006) Biomediated reinforcement of weathered calcareous stones. Journal of Cultural Heritage, 7(1), 49-55.
  • [26] Tiano, P., (1995) Stone reinforcement by calcite crystal precipitation induced by organic matrix macromolecules. Studies in Conservation, 40(3), 171-176.
  • [27] Choi, S. G., Chu, J., Brown, R. C., Wang, K., & Wen, Z., (2017) Sustainable biocement production via microbially induced calcium carbonate precipitation: use of limestone and acetic acid derived from pyrolysis of lignocellulosic biomass. ACS Sustainable Chemistry & Engineering, 5(6), 5183-5190.
  • [28] Zhang, Y., Guo, H. X., & Cheng, X. H., (2015) Role of calcium sources in the strength and microstructure of microbial mortar. Construction and Building Materials, 77, 160-167.
  • [29] Li, Bing., (2015) Geotechnical Properties of Biocement Treated Sand and Clay. Doctoral Thesis, School of Civil and Environmental Engineering, Nanyang Technological University .
  • [30] Chu, J., Stabnikov, V., & Ivanov, V., (2012) Microbially induced calcium carbonate precipitation on surface or in the bulk of soil. Geomicrobiology Journal, 29(6), 544-549.
  • [31] Cheng, L., Shahin, M. A., & Mujah, D., (2016) Influence of key environmental conditions on microbially induced cementation for soil stabilization. Journal of Geotechnical and Geoenvironmental Engineering, 143(1), 04016083.
  • [32] Lee, M. L., Ng, W. S., & Tanaka, Y., (2013) Stress-deformation and compressibility responses of bio-mediated residual soils. Ecological engineering, 60, 142-149.
  • [33] Choi, S. G., Park, S. S., Wu, S., & Chu, J., (2017) Methods for calcium carbonate content measurement of biocemented soils. Journal of Materials in Civil Engineering, 29(11), 06017015.
  • [34] Cui, M. J., Zheng, J. J., Zhang, R. J., Lai, H. J., & Zhang, J., (2017) Influence of cementation level on the strength behaviour of bio-cemented sand. Acta Geotechnica, 12(5), 971-986.
  • [35] Moravej, S., Habibagahi, G., Nikooee, E., & Niazi, A., (2018) Stabilization of dispersive soils by means of biological calcite precipitation. Geoderma, 315, 130-137.
  • [36] Kalantary, F., & Kahani, M., (2015) Evaluation of the ability to control biological precipitation to improve sandy soils. Procedia Earth and Planetary Science, 15, 278-284.
Toplam 36 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Research Articles
Yazarlar

Harun Akoğuz Bu kişi benim 0000-0001-9274-0249

Semet Çelik Bu kişi benim 0000-0002-9674-8579

Özlem Barış Bu kişi benim 0000-0002-2679-5599

Yayımlanma Tarihi 1 Eylül 2020
Gönderilme Tarihi 23 Haziran 2019
Yayımlandığı Sayı Yıl 2019 Cilt: 37 Sayı: 3

Kaynak Göster

Vancouver Akoğuz H, Çelik S, Barış Ö. THE EFFECTS OF DIFFERENT SOURCES OF CALCIUM IN IMPROVEMENT OF SOILS BY MICROBIALLY INDUCED CALCITE PRECIPITATION (MICP). SIGMA. 2020;37(3):953-65.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK https://eds.yildiz.edu.tr/sigma/