An Overview of the Factors Affecting Microbial-Induced Calcite Precipitation and its Potential Application in Soil Improvement
Microbial-induced calcite precipitation (MICP) is a
relatively green and sustainable soil improvement technique. It
utilizes biochemical process that exists naturally in soil to improve
engineering properties of soils. The calcite precipitation process is
uplifted by the mean of injecting higher concentration of urease
positive bacteria and reagents into the soil. The main objective of this
paper is to provide an overview of the factors affecting the MICP in
soil. Several factors were identified including nutrients, bacteria type,
geometric compatibility of bacteria, bacteria cell concentration,
fixation and distribution of bacteria in soil, temperature, reagents
concentration, pH, and injection method. These factors were found to
be essential for promoting successful MICP soil treatment.
Furthermore, a preliminary laboratory test was carried out to
investigate the potential application of the technique in improving the
shear strength and impermeability of a residual soil specimen. The
results showed that both shear strength and impermeability of
residual soil improved significantly upon MICP treatment. The
improvement increased with increasing soil density.
[1] B. B. K. Huat, "Deformation and Shear Strength Characteristics of
Some Tropical Peat and Organic Soils," Pertanika J. Sci. Technol., vol.
14, pp. 61-74, 2006.
[2] S. Kazemian, B. B. K. Huat, A. Prasad, and M. Barghchi, "A state of
art review of peat Geotechnical engineering perspective," Int. J. Phys.
Sci., vol. 6, pp. 1974-1981, 2011.
[3] M. H. Ho and C. M. Chan, "Some Mechanical Properties of Cement
Stabilized Malaysian Soft Clay," World Acad. Sci. Eng. Technol., vol.
74, pp. 24-31, 2011.
[4] R. H. Karol, Chemical grouting and soil stabilization, 3rd ed. New
York: M. Dekker, 2003.
[5] P. P. Xanthakos, L. W. Abramson, and D. A. Bruce, Ground control
and improvement. New York: J. Wiley, 1994.
[6] C. Anagnostopoulos and S. Hadjispyrou, "Laboratory study of an
epoxy resin grouted sand," Ground Improv., vol. 8, pp. 39-45, 2004.
[7] S. Peethamparan, J. Olek, and S. Diamond, "Mechanism of stabilization
of Na-montmorillonite clay with cement kiln dust," Cem. Concr. Res.,
vol. 39, pp. 580-589, 2009.
[8] E. A. Basha, R. Hashim, H. B. Mahmud, and A. S. Muntohar,
"Stabilization of residual soil with rice husk ash and cement," Constr.
Build. Mater., vol. 19, pp. 448-453, 2005.
[9] J. T. DeJong, M. B. Fritzges, and K. N├╝sslein, "Microbially Induced
Cementation to Control Sand Response to Undrained Shear," J.
Geotech. Geoenviron. Eng., vol. 132, pp. 1381-1392, 2006.
[10] W. De Muynck, D. Debrouwer, N. De Belie, and W. Verstraete,
"Bacterial carbonate precipitation improves the durability of
cementitious materials," Cem. Concr. Res., vol. 38, pp. 1005-1014,
2008.
[11] V. Achal, X. Pan, and N. Özyurt, "Improved strength and durability of
fly ash-amended concrete by microbial calcite precipitation," Ecol.
Eng., vol. 37, pp. 554-559, 2011.
[12] D. Sarda, H. Choonia, D. Sarode, and S. Lele, "Biocalcification by
Bacillus pasteurii urease: a novel application," J. Ind. Microbiol.
Biotechnol., vol. 36, pp. 1111-1115, 2009.
[13] M. V. d. Ruyt and W. V. d. Zon, "Biological in situ reinforcement of
sand in near-shore areas," Proc. Inst. Civ. Eng. Geotech. Eng., vol. 162,
pp. 81-83, 2009.
[14] W. Lu, C. Qian, and R. Wang, "Study on soil solidification based on
microbiological precipitation of CaCO3," Sci. China Technol. Sci., vol.
53, pp. 2372-2377, 2010.
[15] C. Qian, Q. Pan, and R. Wang, "Cementation of sand grains based on
carbonate precipitation induced by microorganism," Sci. China
Technol. Sci., vol. 53, pp. 2198-2206, 2010.
[16] A. Gurbuz, Y. D. Sari, Z. N. Yuksekdag, and B. Cinar, "Cementation in
a matrix of loose sandy soil using biological treatment method," Afr. J.
Biotechnol., vol. 10, pp. 7432-7440, 2011.
[17] M. Nemati and G. Voordouw, "Modification of porous media
permeability, using calcium carbonate produced enzymatically in situ,"
Enzyme Microb. Technol., vol. 33, pp. 635-642, 2003.
[18] M. Nemati, E. A. Greene, and G. Voordouw, "Permeability profile
modification using bacterially formed calcium carbonate: comparison
with enzymic option," Process Biochem., vol. 40, pp. 925-933, 2005.
[19] V. Ivanov and J. Chu, "Applications of microorganisms to geotechnical
engineering for bioclogging and biocementation of soil in situ," Rev.
Environ. Sci. Biotechnol., vol. 7, pp. 139-153, 2008.
[20] Y. Fujita, F. G. Ferris, R. D. Lawson, F. S. Colwell, and R. W. Smith,
"Calcium Carbonate Precipitation by Ureolytic Subsurface Bacteria,"
Geomicrobiol. J., vol. 17, pp. 305-318, 2000 2000.
[21] P. Vandevivere and P. Baveye, "Relationship between Transport of
Bacteria and Their Clogging Efficiency in Sand Columns," Appl
Environ Microbiol, vol. 58, pp. 2523-2530, Aug 1992.
[22] G. Z. Abdel Aal, E. A. Atekwana, and E. A. Atekwana, "Effect of
bioclogging in porous media on complex conductivity signatures," J.
Geophys. Res., vol. 115, p. G00G07, 2010.
[23] H. L. Mobley, M. D. Island, and R. P. Hausinger, "Molecular biology
of microbial ureases," Microbiol. Rev., vol. 59, pp. 451-80, Sep 1995.
[24] K. L. Bachmeier, A. E. Williams, J. R. Warmington, and S. S. Bang,
"Urease activity in microbiologically-induced calcite precipitation," J.
Biotechnol., vol. 93, pp. 171-181, 2002.
[25] D. E. Kile, D. D. Eberl, A. R. Hoch, and M. M. Reddy, "An assessment
of calcite crystal growth mechanisms based on crystal size
distributions," Geochim. Cosmochim. Acta, vol. 64, pp. 2937-2950,
2000.
[26] S. Castanier, G. Le Métayer-Levrel, and J.-P. Perthuisot, "Cacarbonates
precipitation and limestone genesis -- the microbiogeologist
point of view," Sediment. Geol., vol. 126, pp. 9-23, 1999.
[27] J. K. Mitchell and J. C. Santamarina, "Biological Considerations in
Geotechnical Engineering," J. Geotech. Geoenviron. Eng., vol. 131, pp.
1222-1233, 2005.
[28] S. Stocks-Fischer, J. K. Galinat, and S. S. Bang, "Microbiological
precipitation of CaCO3," Soil Biol. Biochem., vol. 31, pp. 1563-1571,
1999.
[29] A. A. Qabany, B. Mortensen, B. Martinez, K. Soga, and J. DeJong,
"Microbial Carbonate Precipitation Correlation of S-Wave Velocity
with Calcite Precipitation," Geo-Frontiers 2011, pp. 3993-4001, 2011.
[30] E. S. Kucharski, R. Cord-ruwisch, V. Whiffin, and S. M. Al-thawadi,
"Microbial Biocementation," United States Patent, 2008.
[31] F. Hammes, N. Boon, J. de Villiers, W. Verstraete, and S. D. Siciliano,
"Strain-specific ureolytic microbial calcium carbonate precipitation,"
Appl. Environ. Microbiol., vol. 69, pp. 4901-9, Aug 2003.
[32] K. Van Tittelboom, N. De Belie, W. De Muynck, and W. Verstraete,
"Use of bacteria to repair cracks in concrete," Cem. Concr. Res., vol.
40, pp. 157-166, 2010.
[33] R. Siddique, V. Achal, M. Reddy, and A. Mukherjee, "Improvement in
the compressive strength of cement mortar by the use of a
microorganism - Bacillus megaterium," in Excellence in Concrete
Construction through Innovation. M. C. Limbachiya and H. Kew, Eds.,
United Kingdom: Taylor & Francis, 2008, pp. 27-30.
[34] V. S. Whiffin, L. A. van Paassen, and M. P. Harkes, "Microbial
Carbonate Precipitation as a Soil Improvement Technique,"
Geomicrobiol. J., vol. 24, pp. 417-423, July 2007.
[35] B. Vijay, H. Prashant, and R. Darshak, "Bacterial concrete - An ideal
concrete for historical structures," in Concrete Solutions. CRC Press,
2009.
[36] J. Dick, W. De Windt, B. De Graef, H. Saveyn, P. Van der Meeren, N.
De Belie, and W. Verstraete, "Bio-deposition of a calcium carbonate
layer on degraded limestone by Bacillus species," Biodegradation, vol.
17, pp. 357-367, 2006.
[37] P. Schloss and J. Handelsman, "Status of the microbial census,"
Microbiol. Mol. Biol. Rev., vol. 68, pp. 686-691, 2004.
[38] P. H. Janssen, "Identifying the Dominant Soil Bacterial Taxa in
Libraries of 16S rRNA and 16S rRNA Genes," Appl. Environ.
Microbiol., vol. 72, pp. 1719-1728, March 1, 2006 2006.
[39] R. M. Maier, I. L. Pepper, and C. P. Gerba, Environmental
Microbiology, 2nd ed. China: Elsevier Science, 2009, pp. 366.
[40] G. D. Okwadha and J. Li, "Optimum conditions for microbial carbonate
precipitation," Chemosphere, vol. 81, pp. 1143-8, Nov 2010.
[41] W. Li, L. P. Liu, P. P. Zhou, L. Cao, L. J. Yu, and S. Y. Jiang, "Calcite
precipitation induced by bacteria and bacterially produced carbonic
anhydrase," Curr. Sci., vol. 100, pp. 502-508, 2011.
[42] B. Lian, Q. Hu, J. Chen, J. Ji, and H. Teng, "Carbonate
biomineralization induced by soil bacterium Bacillus megaterium,"
Geochim. Cosmochim. Acta, vol. 70, pp. 5522-5535, 2006.
[43] H. v. Knorre and W. E. krumbein. (2000) Bacterial Calcification.
Microbial Sediments. 25-31.
[44] M. P. Harkes, L. A. van Paassen, J. L. Booster, V. S. Whiffin, and M.
C. M. van Loosdrecht, "Fixation and distribution of bacterial activity in
sand to induce carbonate precipitation for ground reinforcement," Ecol.
Eng., vol. 36, pp. 112-117, 2010.
[45] G. Ritvo, O. Dassa, and M. Kochba, "Salinity and pH effect on the
colloidal properties of suspended particles in super intensive
aquaculture systems," Aquac., vol. 218, pp. 379-386, 2003.
[46] S. Torkzaban, S. S. Tazehkand, S. L. Walker, and S. A. Bradford,
"Transport and fate of bacteria in porous media: Coupled effects of
chemical conditions and pore space geometry," Water Resour. Res.,
vol. 44, p. W04403, 2008.
[47] O. Selinus, Essentials of medical geology : impacts of the natural
environment on public health. Amsterdam ; London: Elsevier
Academic Press, 2005, pp. 483.
[48] M. Z. Jacobson, Fundamentals of atmospheric modeling, 2nd ed.
Cambridge: Cambridge University Press, 2005, pp. 254-255.
[49] S. Doty and W. C. Turner, Energy management handbook, 7th ed.
Lilburn, Ga.: Fairmont Press ; London : Taylor & Francis, 2009, pp.
734.
[50] Abdul Rahim Nik, Baharuddin Kasran, and Azman Hassan, "Soil
temperature regimes under mixed dipterocarp forests of Peninsular
Malaysia " Pertanika J. Sci. Technol., vol. 9, pp. 277-284, 1986.
[51] M. International Society for Environmental Biotechnology and D. L.
Wise, Global environmental biotechnology : proceedings of the Third
Biennial Meeting of the International Society for Environmental
Biotechnology, 15-20 July 1996, Boston, MA U.S.A. Amsterdam ;
Oxford: Elsevier, 1997, pp. 745-746.
[52] D. H. Bergey and D. R. Boone, Bergey's manual of systematic
bacteriology, 2nd ed. New York: Springer, 2009, pp. 34.
[53] A. de Bary, Vergleichende Morphologie und Biologie der Pilze,
Mycetozoen und Bacterien. Leipzig: Wilhelm Engelmann, 1884.
[54] K. Sahrawat, "Effects of temperature and moisture on urease activity in
semi-arid tropical soils," Plant and Soil, vol. 78, pp. 401-408, 1984.
[55] Z. P. Liang, Y. Q. Feng, S. X. Meng, and Z. Y. Liang, "Preparation and
Properties of Urease Immobilized onto Glutaraldehyde Cross-linked
Chitosan Beads," Chin. Chem. Letters, vol. 16, pp. 135-138, 2005.
[56] Y. Y. Chen, K. A. Clancy, and R. A. Burne, "Streptococcus salivarius
urease: genetic and biochemical characterization and expression in a
dental plaque streptococcus," Infect. Immun., vol. 64, pp. 585-92, Feb
1996.
[57] M. a. A. Rivadeneyra, J. Párraga, R. Delgado, A. Ramos-Cormenzana,
and G. Delgado, "Biomineralization of carbonates by Halobacillus
trueperi in solid and liquid media with different salinities," FEMS
Microbiol. Ecol., vol. 48, pp. 39-46, 2004.
[58] W. De Muynck, K. Verbeken, N. De Belie, and W. Verstraete,
"Influence of urea and calcium dosage on the effectiveness of
bacterially induced carbonate precipitation on limestone," Ecol. Eng.,
vol. 36, pp. 99-111, 2010.
[59] M. A. Rivadeneyra, G. Delgado, A. Ramos-Cormenzana, and R.
Delgado, "Biomineralization of carbonates by Halomonas eurihalina in
solid and liquid media with different salinities: crystal formation
sequence," Res. Microbiol., vol. 149, pp. 277-87, 1998.
[60] M. A. Rivadeneyra, G. Delgado, M. Soriano, A. Ramos-Cormenzana,
and R. Delgado, "Precipitation of carbonates by Nesterenkonia halobia
in liquid media," Chemosphere, vol. 41, pp. 617-24, Aug 2000.
[61] M. R. Ferrer, J. Quevedo-Sarmiento, V. Bejar, R. Delgado, A.
Ramos-Cormenzana, and M. A. Rivadeneyra, "Calcium carbonate
formation by Deleya halophila: Effect of salt concentration and
incubation temperature," Geomicrobiol. J., vol. 6, pp. 49-57, 1988.
[62] M. R. Ferrer, J. Quevedo-Sarmiento, M. A. Rivadeneyra, V. Bejar, R.
Delgado, and A. Ramos-Cormenzana, "Calcium carbonate precipitation
by two groups of moderately halophilic microorganisms at different
temperatures and salt concentrations," Curr. Microbiol., vol. 17, pp.
221-227, 1988.
[63] M. A. Rivadeneyra, R. Delgado, G. Delgado, A. D. Moral, M. R.
Ferrer, and A. Ramos-Cormenzana, "Precipitation of carbonates by
Bacillus sp. isolated from saline soils," Geomicrobiol. J., vol. 11, pp.
175-184, 1993.
[64] M. A. Rivadeneyra, R. Delgado, A. del Moral, M. R. Ferrer, and A.
Ramos-Cormenzana, "Precipatation of calcium carbonate by Vibrio
spp. from an inland saltern," FEMS Microbiol. Ecol., vol. 13, pp. 197-
204, 1994.
[65] D. J. Evans, Jr., D. G. Evans, S. S. Kirkpatrick, and D. Y. Graham,
"Characterization of the Helicobacter pylori urease and purification of
its subunits," Microb. Pathog., vol. 10, pp. 15-26, 1991.
[66] K. D. Arunachalam, K. S. Sathyanarayanan, B. S. Darshan, and R. B.
Raja, "Studies on the characterisation of Biosealant properties of
Bacillus sphaericus," Int. J. Eng. Sci. Technol., vol. 2, pp. 270-277,
2010.
[67] B. C. Martinez, T. H. Barkouki, J. D. DeJong, and T. R. Ginn,
"Upscaling of Microbial Induced Calcite Precipitation in 0.5m Columns
Experimental and Modeling Results," Geo-Frontiers 2011, pp. 4049-
4059, 2011.
[68] T. Barkouki, B. Martinez, B. Mortensen, T. Weathers, J. De Jong, T.
Ginn, N. Spycher, R. Smith, and Y. Fujita, "Forward and Inverse Bio-
Geochemical Modeling of Microbially Induced Calcite Precipitation in
Half-Meter Column Experiments," Transp. Porous Med., pp. 1-17,
2010.
[69] D. L. Stoner, S. M. Watson, R. D. Stedtfeld, P. Meakin, L. K. Griffel,
T. L. Tyler, L. M. Pegram, J. M. Barnes, and V. A. Deason,
"Application of stereolithographic custom models for studying the
impact of biofilms and mineral precipitation on fluid flow," Appl.
Environ. Microbiol., vol. 71, pp. 8721-8, Dec 2005.
[70] BSI, "British Standard 1377: 1990 " in Methods of test for soils for civil
engineering purposes, ed. United Kingdom: BSI Group, 1990.
[1] B. B. K. Huat, "Deformation and Shear Strength Characteristics of
Some Tropical Peat and Organic Soils," Pertanika J. Sci. Technol., vol.
14, pp. 61-74, 2006.
[2] S. Kazemian, B. B. K. Huat, A. Prasad, and M. Barghchi, "A state of
art review of peat Geotechnical engineering perspective," Int. J. Phys.
Sci., vol. 6, pp. 1974-1981, 2011.
[3] M. H. Ho and C. M. Chan, "Some Mechanical Properties of Cement
Stabilized Malaysian Soft Clay," World Acad. Sci. Eng. Technol., vol.
74, pp. 24-31, 2011.
[4] R. H. Karol, Chemical grouting and soil stabilization, 3rd ed. New
York: M. Dekker, 2003.
[5] P. P. Xanthakos, L. W. Abramson, and D. A. Bruce, Ground control
and improvement. New York: J. Wiley, 1994.
[6] C. Anagnostopoulos and S. Hadjispyrou, "Laboratory study of an
epoxy resin grouted sand," Ground Improv., vol. 8, pp. 39-45, 2004.
[7] S. Peethamparan, J. Olek, and S. Diamond, "Mechanism of stabilization
of Na-montmorillonite clay with cement kiln dust," Cem. Concr. Res.,
vol. 39, pp. 580-589, 2009.
[8] E. A. Basha, R. Hashim, H. B. Mahmud, and A. S. Muntohar,
"Stabilization of residual soil with rice husk ash and cement," Constr.
Build. Mater., vol. 19, pp. 448-453, 2005.
[9] J. T. DeJong, M. B. Fritzges, and K. N├╝sslein, "Microbially Induced
Cementation to Control Sand Response to Undrained Shear," J.
Geotech. Geoenviron. Eng., vol. 132, pp. 1381-1392, 2006.
[10] W. De Muynck, D. Debrouwer, N. De Belie, and W. Verstraete,
"Bacterial carbonate precipitation improves the durability of
cementitious materials," Cem. Concr. Res., vol. 38, pp. 1005-1014,
2008.
[11] V. Achal, X. Pan, and N. Özyurt, "Improved strength and durability of
fly ash-amended concrete by microbial calcite precipitation," Ecol.
Eng., vol. 37, pp. 554-559, 2011.
[12] D. Sarda, H. Choonia, D. Sarode, and S. Lele, "Biocalcification by
Bacillus pasteurii urease: a novel application," J. Ind. Microbiol.
Biotechnol., vol. 36, pp. 1111-1115, 2009.
[13] M. V. d. Ruyt and W. V. d. Zon, "Biological in situ reinforcement of
sand in near-shore areas," Proc. Inst. Civ. Eng. Geotech. Eng., vol. 162,
pp. 81-83, 2009.
[14] W. Lu, C. Qian, and R. Wang, "Study on soil solidification based on
microbiological precipitation of CaCO3," Sci. China Technol. Sci., vol.
53, pp. 2372-2377, 2010.
[15] C. Qian, Q. Pan, and R. Wang, "Cementation of sand grains based on
carbonate precipitation induced by microorganism," Sci. China
Technol. Sci., vol. 53, pp. 2198-2206, 2010.
[16] A. Gurbuz, Y. D. Sari, Z. N. Yuksekdag, and B. Cinar, "Cementation in
a matrix of loose sandy soil using biological treatment method," Afr. J.
Biotechnol., vol. 10, pp. 7432-7440, 2011.
[17] M. Nemati and G. Voordouw, "Modification of porous media
permeability, using calcium carbonate produced enzymatically in situ,"
Enzyme Microb. Technol., vol. 33, pp. 635-642, 2003.
[18] M. Nemati, E. A. Greene, and G. Voordouw, "Permeability profile
modification using bacterially formed calcium carbonate: comparison
with enzymic option," Process Biochem., vol. 40, pp. 925-933, 2005.
[19] V. Ivanov and J. Chu, "Applications of microorganisms to geotechnical
engineering for bioclogging and biocementation of soil in situ," Rev.
Environ. Sci. Biotechnol., vol. 7, pp. 139-153, 2008.
[20] Y. Fujita, F. G. Ferris, R. D. Lawson, F. S. Colwell, and R. W. Smith,
"Calcium Carbonate Precipitation by Ureolytic Subsurface Bacteria,"
Geomicrobiol. J., vol. 17, pp. 305-318, 2000 2000.
[21] P. Vandevivere and P. Baveye, "Relationship between Transport of
Bacteria and Their Clogging Efficiency in Sand Columns," Appl
Environ Microbiol, vol. 58, pp. 2523-2530, Aug 1992.
[22] G. Z. Abdel Aal, E. A. Atekwana, and E. A. Atekwana, "Effect of
bioclogging in porous media on complex conductivity signatures," J.
Geophys. Res., vol. 115, p. G00G07, 2010.
[23] H. L. Mobley, M. D. Island, and R. P. Hausinger, "Molecular biology
of microbial ureases," Microbiol. Rev., vol. 59, pp. 451-80, Sep 1995.
[24] K. L. Bachmeier, A. E. Williams, J. R. Warmington, and S. S. Bang,
"Urease activity in microbiologically-induced calcite precipitation," J.
Biotechnol., vol. 93, pp. 171-181, 2002.
[25] D. E. Kile, D. D. Eberl, A. R. Hoch, and M. M. Reddy, "An assessment
of calcite crystal growth mechanisms based on crystal size
distributions," Geochim. Cosmochim. Acta, vol. 64, pp. 2937-2950,
2000.
[26] S. Castanier, G. Le Métayer-Levrel, and J.-P. Perthuisot, "Cacarbonates
precipitation and limestone genesis -- the microbiogeologist
point of view," Sediment. Geol., vol. 126, pp. 9-23, 1999.
[27] J. K. Mitchell and J. C. Santamarina, "Biological Considerations in
Geotechnical Engineering," J. Geotech. Geoenviron. Eng., vol. 131, pp.
1222-1233, 2005.
[28] S. Stocks-Fischer, J. K. Galinat, and S. S. Bang, "Microbiological
precipitation of CaCO3," Soil Biol. Biochem., vol. 31, pp. 1563-1571,
1999.
[29] A. A. Qabany, B. Mortensen, B. Martinez, K. Soga, and J. DeJong,
"Microbial Carbonate Precipitation Correlation of S-Wave Velocity
with Calcite Precipitation," Geo-Frontiers 2011, pp. 3993-4001, 2011.
[30] E. S. Kucharski, R. Cord-ruwisch, V. Whiffin, and S. M. Al-thawadi,
"Microbial Biocementation," United States Patent, 2008.
[31] F. Hammes, N. Boon, J. de Villiers, W. Verstraete, and S. D. Siciliano,
"Strain-specific ureolytic microbial calcium carbonate precipitation,"
Appl. Environ. Microbiol., vol. 69, pp. 4901-9, Aug 2003.
[32] K. Van Tittelboom, N. De Belie, W. De Muynck, and W. Verstraete,
"Use of bacteria to repair cracks in concrete," Cem. Concr. Res., vol.
40, pp. 157-166, 2010.
[33] R. Siddique, V. Achal, M. Reddy, and A. Mukherjee, "Improvement in
the compressive strength of cement mortar by the use of a
microorganism - Bacillus megaterium," in Excellence in Concrete
Construction through Innovation. M. C. Limbachiya and H. Kew, Eds.,
United Kingdom: Taylor & Francis, 2008, pp. 27-30.
[34] V. S. Whiffin, L. A. van Paassen, and M. P. Harkes, "Microbial
Carbonate Precipitation as a Soil Improvement Technique,"
Geomicrobiol. J., vol. 24, pp. 417-423, July 2007.
[35] B. Vijay, H. Prashant, and R. Darshak, "Bacterial concrete - An ideal
concrete for historical structures," in Concrete Solutions. CRC Press,
2009.
[36] J. Dick, W. De Windt, B. De Graef, H. Saveyn, P. Van der Meeren, N.
De Belie, and W. Verstraete, "Bio-deposition of a calcium carbonate
layer on degraded limestone by Bacillus species," Biodegradation, vol.
17, pp. 357-367, 2006.
[37] P. Schloss and J. Handelsman, "Status of the microbial census,"
Microbiol. Mol. Biol. Rev., vol. 68, pp. 686-691, 2004.
[38] P. H. Janssen, "Identifying the Dominant Soil Bacterial Taxa in
Libraries of 16S rRNA and 16S rRNA Genes," Appl. Environ.
Microbiol., vol. 72, pp. 1719-1728, March 1, 2006 2006.
[39] R. M. Maier, I. L. Pepper, and C. P. Gerba, Environmental
Microbiology, 2nd ed. China: Elsevier Science, 2009, pp. 366.
[40] G. D. Okwadha and J. Li, "Optimum conditions for microbial carbonate
precipitation," Chemosphere, vol. 81, pp. 1143-8, Nov 2010.
[41] W. Li, L. P. Liu, P. P. Zhou, L. Cao, L. J. Yu, and S. Y. Jiang, "Calcite
precipitation induced by bacteria and bacterially produced carbonic
anhydrase," Curr. Sci., vol. 100, pp. 502-508, 2011.
[42] B. Lian, Q. Hu, J. Chen, J. Ji, and H. Teng, "Carbonate
biomineralization induced by soil bacterium Bacillus megaterium,"
Geochim. Cosmochim. Acta, vol. 70, pp. 5522-5535, 2006.
[43] H. v. Knorre and W. E. krumbein. (2000) Bacterial Calcification.
Microbial Sediments. 25-31.
[44] M. P. Harkes, L. A. van Paassen, J. L. Booster, V. S. Whiffin, and M.
C. M. van Loosdrecht, "Fixation and distribution of bacterial activity in
sand to induce carbonate precipitation for ground reinforcement," Ecol.
Eng., vol. 36, pp. 112-117, 2010.
[45] G. Ritvo, O. Dassa, and M. Kochba, "Salinity and pH effect on the
colloidal properties of suspended particles in super intensive
aquaculture systems," Aquac., vol. 218, pp. 379-386, 2003.
[46] S. Torkzaban, S. S. Tazehkand, S. L. Walker, and S. A. Bradford,
"Transport and fate of bacteria in porous media: Coupled effects of
chemical conditions and pore space geometry," Water Resour. Res.,
vol. 44, p. W04403, 2008.
[47] O. Selinus, Essentials of medical geology : impacts of the natural
environment on public health. Amsterdam ; London: Elsevier
Academic Press, 2005, pp. 483.
[48] M. Z. Jacobson, Fundamentals of atmospheric modeling, 2nd ed.
Cambridge: Cambridge University Press, 2005, pp. 254-255.
[49] S. Doty and W. C. Turner, Energy management handbook, 7th ed.
Lilburn, Ga.: Fairmont Press ; London : Taylor & Francis, 2009, pp.
734.
[50] Abdul Rahim Nik, Baharuddin Kasran, and Azman Hassan, "Soil
temperature regimes under mixed dipterocarp forests of Peninsular
Malaysia " Pertanika J. Sci. Technol., vol. 9, pp. 277-284, 1986.
[51] M. International Society for Environmental Biotechnology and D. L.
Wise, Global environmental biotechnology : proceedings of the Third
Biennial Meeting of the International Society for Environmental
Biotechnology, 15-20 July 1996, Boston, MA U.S.A. Amsterdam ;
Oxford: Elsevier, 1997, pp. 745-746.
[52] D. H. Bergey and D. R. Boone, Bergey's manual of systematic
bacteriology, 2nd ed. New York: Springer, 2009, pp. 34.
[53] A. de Bary, Vergleichende Morphologie und Biologie der Pilze,
Mycetozoen und Bacterien. Leipzig: Wilhelm Engelmann, 1884.
[54] K. Sahrawat, "Effects of temperature and moisture on urease activity in
semi-arid tropical soils," Plant and Soil, vol. 78, pp. 401-408, 1984.
[55] Z. P. Liang, Y. Q. Feng, S. X. Meng, and Z. Y. Liang, "Preparation and
Properties of Urease Immobilized onto Glutaraldehyde Cross-linked
Chitosan Beads," Chin. Chem. Letters, vol. 16, pp. 135-138, 2005.
[56] Y. Y. Chen, K. A. Clancy, and R. A. Burne, "Streptococcus salivarius
urease: genetic and biochemical characterization and expression in a
dental plaque streptococcus," Infect. Immun., vol. 64, pp. 585-92, Feb
1996.
[57] M. a. A. Rivadeneyra, J. Párraga, R. Delgado, A. Ramos-Cormenzana,
and G. Delgado, "Biomineralization of carbonates by Halobacillus
trueperi in solid and liquid media with different salinities," FEMS
Microbiol. Ecol., vol. 48, pp. 39-46, 2004.
[58] W. De Muynck, K. Verbeken, N. De Belie, and W. Verstraete,
"Influence of urea and calcium dosage on the effectiveness of
bacterially induced carbonate precipitation on limestone," Ecol. Eng.,
vol. 36, pp. 99-111, 2010.
[59] M. A. Rivadeneyra, G. Delgado, A. Ramos-Cormenzana, and R.
Delgado, "Biomineralization of carbonates by Halomonas eurihalina in
solid and liquid media with different salinities: crystal formation
sequence," Res. Microbiol., vol. 149, pp. 277-87, 1998.
[60] M. A. Rivadeneyra, G. Delgado, M. Soriano, A. Ramos-Cormenzana,
and R. Delgado, "Precipitation of carbonates by Nesterenkonia halobia
in liquid media," Chemosphere, vol. 41, pp. 617-24, Aug 2000.
[61] M. R. Ferrer, J. Quevedo-Sarmiento, V. Bejar, R. Delgado, A.
Ramos-Cormenzana, and M. A. Rivadeneyra, "Calcium carbonate
formation by Deleya halophila: Effect of salt concentration and
incubation temperature," Geomicrobiol. J., vol. 6, pp. 49-57, 1988.
[62] M. R. Ferrer, J. Quevedo-Sarmiento, M. A. Rivadeneyra, V. Bejar, R.
Delgado, and A. Ramos-Cormenzana, "Calcium carbonate precipitation
by two groups of moderately halophilic microorganisms at different
temperatures and salt concentrations," Curr. Microbiol., vol. 17, pp.
221-227, 1988.
[63] M. A. Rivadeneyra, R. Delgado, G. Delgado, A. D. Moral, M. R.
Ferrer, and A. Ramos-Cormenzana, "Precipitation of carbonates by
Bacillus sp. isolated from saline soils," Geomicrobiol. J., vol. 11, pp.
175-184, 1993.
[64] M. A. Rivadeneyra, R. Delgado, A. del Moral, M. R. Ferrer, and A.
Ramos-Cormenzana, "Precipatation of calcium carbonate by Vibrio
spp. from an inland saltern," FEMS Microbiol. Ecol., vol. 13, pp. 197-
204, 1994.
[65] D. J. Evans, Jr., D. G. Evans, S. S. Kirkpatrick, and D. Y. Graham,
"Characterization of the Helicobacter pylori urease and purification of
its subunits," Microb. Pathog., vol. 10, pp. 15-26, 1991.
[66] K. D. Arunachalam, K. S. Sathyanarayanan, B. S. Darshan, and R. B.
Raja, "Studies on the characterisation of Biosealant properties of
Bacillus sphaericus," Int. J. Eng. Sci. Technol., vol. 2, pp. 270-277,
2010.
[67] B. C. Martinez, T. H. Barkouki, J. D. DeJong, and T. R. Ginn,
"Upscaling of Microbial Induced Calcite Precipitation in 0.5m Columns
Experimental and Modeling Results," Geo-Frontiers 2011, pp. 4049-
4059, 2011.
[68] T. Barkouki, B. Martinez, B. Mortensen, T. Weathers, J. De Jong, T.
Ginn, N. Spycher, R. Smith, and Y. Fujita, "Forward and Inverse Bio-
Geochemical Modeling of Microbially Induced Calcite Precipitation in
Half-Meter Column Experiments," Transp. Porous Med., pp. 1-17,
2010.
[69] D. L. Stoner, S. M. Watson, R. D. Stedtfeld, P. Meakin, L. K. Griffel,
T. L. Tyler, L. M. Pegram, J. M. Barnes, and V. A. Deason,
"Application of stereolithographic custom models for studying the
impact of biofilms and mineral precipitation on fluid flow," Appl.
Environ. Microbiol., vol. 71, pp. 8721-8, Dec 2005.
[70] BSI, "British Standard 1377: 1990 " in Methods of test for soils for civil
engineering purposes, ed. United Kingdom: BSI Group, 1990.
@article{"International Journal of Architectural, Civil and Construction Sciences:64244", author = "Wei-Soon Ng and Min-Lee Lee and Siew-Ling Hii", title = "An Overview of the Factors Affecting Microbial-Induced Calcite Precipitation and its Potential Application in Soil Improvement", abstract = "Microbial-induced calcite precipitation (MICP) is a
relatively green and sustainable soil improvement technique. It
utilizes biochemical process that exists naturally in soil to improve
engineering properties of soils. The calcite precipitation process is
uplifted by the mean of injecting higher concentration of urease
positive bacteria and reagents into the soil. The main objective of this
paper is to provide an overview of the factors affecting the MICP in
soil. Several factors were identified including nutrients, bacteria type,
geometric compatibility of bacteria, bacteria cell concentration,
fixation and distribution of bacteria in soil, temperature, reagents
concentration, pH, and injection method. These factors were found to
be essential for promoting successful MICP soil treatment.
Furthermore, a preliminary laboratory test was carried out to
investigate the potential application of the technique in improving the
shear strength and impermeability of a residual soil specimen. The
results showed that both shear strength and impermeability of
residual soil improved significantly upon MICP treatment. The
improvement increased with increasing soil density.", keywords = "Bacteria, biocementation, bioclogging, calcite
precipitation, soil improvement.", volume = "6", number = "2", pages = "210-7", }
