Review: Microbial induced mineralization of calcium carbonate for self-healing concrete
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Abstract. Elkhateeb WA, Elnahas MO, Daba GM. 2021. Review: Microbial induced mineralization of calcium carbonate for self-Healing concrete. Asian J Nat Prod Biochem 19: 1-9. Low-cost solutions achieving concrete self-healing are attracting researchers’ attention. Generally, a concrete self-healing mechanism has been accomplished so far by three approaches: autogenous healing, encapsulation of polymeric material, and microbial-induced mineralization of calcium carbonate. The microbial approach seems an attractive, potent, and relatively cheap way to achieve concrete self-healing. Hence, this review elucidates the microbial concrete self-healing mechanisms and compares the roles of fungal and bacterial mediated self-healing concrete.
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References
Ahmad A, Rautaray D, Sastry M. 2004. Biogenic calcium carbonate: calcite crystals of variable morphology by the reaction of aqueous Ca2+ ions with fungi. Adv. Funct. Mater. 14: 1075–1080.
Ataie FF. 2019. Influence of Cementitious System Composition on the Retarding Effects of Borax and Zinc Oxide, Materials 12(2019): 2340.
Bashir J, Kathwari I, Tiwary A, Singh K. 2016. Bio concrete-the self-healing concrete, Indian Journal of Science and Technology 9: 1-5.
Bindschedler S, Cailleau G, Verrecchia E. 2016. Role of fungi in the biomineralization of calcite. Minerals 6(2): 41–59.
Chahal R. 2012. Siddique, A. Rajor, Influence of bacteria on the compressive strength, water absorption and rapid chloride permeability of fly ash concrete, Construction and Building Materials 28: 351-356.
De Muynck W, De Belie N, Verstraete W. 2010. Microbial carbonate precipitation improves the durability of cementitious materials: a review. Ecol. Eng. 36: 118–36.
De Muynck W, Debrouwer D, De Belie N, Verstraete W. 2008. Bacterial carbonate precipitation improves the durability of cementitious materials. Cem. Concr. Res. 38: 1005–1014.
De Rooij M, Van Tittelboom K, De Belie N, Schlangen E. 2013. Self-healing phenomena in cement-Based materials: state-of-the-art report of RILEM technical committee 221-SHC: self-Healing phenomena in cement-Based materials, Springer 2013.
Dias MA, Lacerda IC, Pimentel PF, De Castro HF, Rosa CA. 2002. Removal of heavy metals by an Aspergillus terreus strain immobilized in a polyurethane matrix. Letters in applied microbiology 34(1): 46-50.
Dick J, De Windt W, De Graef B, Saveyn H, Van der Meeren P, De Belie N. 2006. Bio-deposition of a calcium carbonate layer on degraded limestone by Bacillus species. Biodegradation 17: 357–367.
Dry C. 1994. Matrix cracking repair and filling using active and passive modes for smart timed release of chemicals from fibers into cement matrices. Smart Material Structure 3: 118–123.
Edvardsen C. 1999. Water permeability and autogenous healing of cracks in concrete. ACI Mater. J. 96: 448–454.
Ersan YC, De Belie N, Boon N. 2015. Microbially induced CaCO3 precipitation through denitrification: an optimization study in minimal nutrient environment. Biochem. Eng. J. 101: 108–118.
Gavimath C, Mali B, Hooli V, Mallpur J, Patil A, Gaddi D, Ternikar C, Ravishankera B. 2012. Potential application of bacteria to improve the strength of cement concrete, International journal of advanced biotechnology and research 3: 541-544.
Gharieb MM, Sayer JA, Gadd GM. 1998. Solubilization of natural gypsum (CaSO42H2O) and formation of calcium oxalate by Aspergillus niger and Serpula himantioides, Mycol. Res. 102: 825–830.
Ghosh P, Mandal S, Chattopadhyay B, Pal S. 2005. Use of microorganism to improve the strength of cement mortar, Cement and Concrete Research 35: 1980-1983.
Isaacs B, Lark R, Jefferson T, Davies R, Dunn S. 2013. Crack healing of cementitious materials using shrinkable polymer tendons, Structural Concrete 14: 138-147.
Jin C, Yu R, Shui, Z. 2018. Fungi: A Neglected Candidate for the Application of Self-Healing Concrete. Frontiers in Built Environment 4(62): 1-8.
Jonkers H. 2011. Bacteria-based self-healing concrete, Heron, 56 (1/2), (2011).
Jonkers HM, Thijssen A, Muyzer G, Copuroglu O, Schlangen E. 2010. Application of bacteria as self-healing agent for the development of sustainable concrete. Ecol. Eng. 36: 230–235.
Jonkers HM. 2007. Self healing concrete: a biological approach, Self healing materials, Springer 195-204.
Jonkers HM. 2011. Bacteria-based self-healing concrete. Heron 56: 1-122.
Kavia K, Hema C. 2015. Dressing of structural cracks using Bio Concrete, Indian Journal of Science and Technology 8: 1-4.
Khaliq W, Ehsan MB. 2016. Crack healing in concrete using various bio influenced self-healing techniques. Constr. Build. Mater. 102: 349–357.
Kumari B. 2015. Microbial concrete: A multi-purpose building material-An overview, International Journal of Advances in Engineering & Technology 7:1608-1619.
Luo J, Chen X, Crump J, Zhou H, Davies D, Zhou G, Jin C. 2018. Interactions of fungi with concrete: significant importance for bio-based self-healing concrete. Construction and building materials, 164: 275-285.?
Magan N. 2007. Fungi in extreme environments. The Mycota 4: 85-103.
Maheswaran S, Dasuru S, Murthy A, Bhuvaneshwari B, Kumar V, Palani G, Iyer N, Krishnamoorthy N, Sandhya S. 2014. Strength improvement studies using new type wild strain Bacillus cereus on cement mortar, Current science 50-57.
Menon RR, Luo J, Chen X, Zhou H, Liu Z, Zhou G, Zhang N, Jin C. 2019. Screening of fungi for potential application of self-healing concrete. Scientific reports 9(1): 1-12.
Morsali S. Isildar G, Tahni A. 2019. The application of bacteria as a main factor in self-healing concrete technology, Journal of Building Pathology and Rehabilitation 4(2019) 7.
Neville AM. 1996. Properties of Concrete, Pearson Higher Education, New Jersey, 1996.
Ramachandran SK, Ramakrishnan V, Bang S. 2001. Remediation of concrete using micro-organisms, ACI Materials Journal-American Concrete Institute 98: 3-9.
Rao M, Reddy S, Hafsa M, Veena P, Anusha P. 2013. Bioengineered concrete-a sustainable self-healing construction material, Research journal of engineering sciences ISSN, 2278 (2013) 9472.
Rautaray D, Ahmad A, Sastry M. 2003. Biosynthesis of CaCO3 crystals of complex morphology using a fungus and an actinomycete. J. Am. Chem. Soc. 125: 14656–14657.
Rautaray D, Ahmad A, Sastry M. 2004. Biological synthesis of metal carbonate minerals using fungi and actinomycetes. J. Mater. Chem. 14: 2333–2340.
Sayer JA, Kierans M, Gadd GM. 1997. Solubilisation of some naturally occurring metal-bearing minerals, limescale and lead phosphate by Aspergillus niger, FEMS Microbiol. Lett. 154: 29–35.
Seifan M, Samani A, Berenjian A. 2016. Bioconcrete: next generation of self-healing concrete. Appl. Microbiol. Biotechnol. 100: 2591–2602.
Setlow P. 1994. Mechanisms which contribute to the long?term survival of spores of Bacillus species, Journal of Applied Bacteriology 76: 49S-60S.
Sheir DH, Amer O, Elkhateeb WA, Daba GM. 2020. Elucidation of Myco-deterioration affecting Calcareous Construction Materials of the Egyptian Architectural Heritage. Boreal environment research 25: 27-56.
Ter Heide N, Schlangen E. 2007. Self-healing of early age cracks in concrete, First international conference on self healing materials 1-12.
Ter Heide N. 2005. Crack healing in hydrating concrete, Delft University of Technology 12-82.
Verrecchia EP. 2000. Fungi and sediments, in: R.E. Riding, S.M. Awramik (Eds.), Microbial Sediments, Springer-Verlag, Berlin 2000.
Vijay K, Murmu M. Deo S. 2017. Bacteria based self healing concrete–A review, Construction and Building Materials 152: 1008-1014.
Wang JY, De Belie N, Verstraete W. 2012. Diatomaceous earth as a protective vehicle for bacteria applied for self-healing concrete. J. Ind. Microbiol. Biotechnol. 39: 567–577.
Yang Y, Ma L, Huang J, Gu C, Xu Z, Liu J, Ni T. 2019. Evaluation of the thermal and shrinkage stresses in restrained high-performance concrete, Materials 12(2019): 3680.
Yang G, Gu C, Bao T, Cui Z, Kan K. 2016. Research on early-warning index of the spatial temperature field in concrete dams, SpringerPlus 5(2016): 1968.
Zhang J, Liu Y, Feng T, Zhou M, Zhao L, Zhou A. 2017. Immobilizing bacteria in expanded perlite for the crack self-healing in concrete. Constr. Build. Mater. 148: 610–617.
Zhang X. Qian C. 2020. Engineering Application of Microbial Self-healing Concrete in Lock Channel Wall, Case Studies in Construction Materials, (2020) e00398.
Zhu T, Dittrich M. 2016. Carbonate precipitation through microbial activities in natural environment, and their potential in biotechnology: a review. Frontiers in bioengineering and biotechnology 4: 4-25.
Ataie FF. 2019. Influence of Cementitious System Composition on the Retarding Effects of Borax and Zinc Oxide, Materials 12(2019): 2340.
Bashir J, Kathwari I, Tiwary A, Singh K. 2016. Bio concrete-the self-healing concrete, Indian Journal of Science and Technology 9: 1-5.
Bindschedler S, Cailleau G, Verrecchia E. 2016. Role of fungi in the biomineralization of calcite. Minerals 6(2): 41–59.
Chahal R. 2012. Siddique, A. Rajor, Influence of bacteria on the compressive strength, water absorption and rapid chloride permeability of fly ash concrete, Construction and Building Materials 28: 351-356.
De Muynck W, De Belie N, Verstraete W. 2010. Microbial carbonate precipitation improves the durability of cementitious materials: a review. Ecol. Eng. 36: 118–36.
De Muynck W, Debrouwer D, De Belie N, Verstraete W. 2008. Bacterial carbonate precipitation improves the durability of cementitious materials. Cem. Concr. Res. 38: 1005–1014.
De Rooij M, Van Tittelboom K, De Belie N, Schlangen E. 2013. Self-healing phenomena in cement-Based materials: state-of-the-art report of RILEM technical committee 221-SHC: self-Healing phenomena in cement-Based materials, Springer 2013.
Dias MA, Lacerda IC, Pimentel PF, De Castro HF, Rosa CA. 2002. Removal of heavy metals by an Aspergillus terreus strain immobilized in a polyurethane matrix. Letters in applied microbiology 34(1): 46-50.
Dick J, De Windt W, De Graef B, Saveyn H, Van der Meeren P, De Belie N. 2006. Bio-deposition of a calcium carbonate layer on degraded limestone by Bacillus species. Biodegradation 17: 357–367.
Dry C. 1994. Matrix cracking repair and filling using active and passive modes for smart timed release of chemicals from fibers into cement matrices. Smart Material Structure 3: 118–123.
Edvardsen C. 1999. Water permeability and autogenous healing of cracks in concrete. ACI Mater. J. 96: 448–454.
Ersan YC, De Belie N, Boon N. 2015. Microbially induced CaCO3 precipitation through denitrification: an optimization study in minimal nutrient environment. Biochem. Eng. J. 101: 108–118.
Gavimath C, Mali B, Hooli V, Mallpur J, Patil A, Gaddi D, Ternikar C, Ravishankera B. 2012. Potential application of bacteria to improve the strength of cement concrete, International journal of advanced biotechnology and research 3: 541-544.
Gharieb MM, Sayer JA, Gadd GM. 1998. Solubilization of natural gypsum (CaSO42H2O) and formation of calcium oxalate by Aspergillus niger and Serpula himantioides, Mycol. Res. 102: 825–830.
Ghosh P, Mandal S, Chattopadhyay B, Pal S. 2005. Use of microorganism to improve the strength of cement mortar, Cement and Concrete Research 35: 1980-1983.
Isaacs B, Lark R, Jefferson T, Davies R, Dunn S. 2013. Crack healing of cementitious materials using shrinkable polymer tendons, Structural Concrete 14: 138-147.
Jin C, Yu R, Shui, Z. 2018. Fungi: A Neglected Candidate for the Application of Self-Healing Concrete. Frontiers in Built Environment 4(62): 1-8.
Jonkers H. 2011. Bacteria-based self-healing concrete, Heron, 56 (1/2), (2011).
Jonkers HM, Thijssen A, Muyzer G, Copuroglu O, Schlangen E. 2010. Application of bacteria as self-healing agent for the development of sustainable concrete. Ecol. Eng. 36: 230–235.
Jonkers HM. 2007. Self healing concrete: a biological approach, Self healing materials, Springer 195-204.
Jonkers HM. 2011. Bacteria-based self-healing concrete. Heron 56: 1-122.
Kavia K, Hema C. 2015. Dressing of structural cracks using Bio Concrete, Indian Journal of Science and Technology 8: 1-4.
Khaliq W, Ehsan MB. 2016. Crack healing in concrete using various bio influenced self-healing techniques. Constr. Build. Mater. 102: 349–357.
Kumari B. 2015. Microbial concrete: A multi-purpose building material-An overview, International Journal of Advances in Engineering & Technology 7:1608-1619.
Luo J, Chen X, Crump J, Zhou H, Davies D, Zhou G, Jin C. 2018. Interactions of fungi with concrete: significant importance for bio-based self-healing concrete. Construction and building materials, 164: 275-285.?
Magan N. 2007. Fungi in extreme environments. The Mycota 4: 85-103.
Maheswaran S, Dasuru S, Murthy A, Bhuvaneshwari B, Kumar V, Palani G, Iyer N, Krishnamoorthy N, Sandhya S. 2014. Strength improvement studies using new type wild strain Bacillus cereus on cement mortar, Current science 50-57.
Menon RR, Luo J, Chen X, Zhou H, Liu Z, Zhou G, Zhang N, Jin C. 2019. Screening of fungi for potential application of self-healing concrete. Scientific reports 9(1): 1-12.
Morsali S. Isildar G, Tahni A. 2019. The application of bacteria as a main factor in self-healing concrete technology, Journal of Building Pathology and Rehabilitation 4(2019) 7.
Neville AM. 1996. Properties of Concrete, Pearson Higher Education, New Jersey, 1996.
Ramachandran SK, Ramakrishnan V, Bang S. 2001. Remediation of concrete using micro-organisms, ACI Materials Journal-American Concrete Institute 98: 3-9.
Rao M, Reddy S, Hafsa M, Veena P, Anusha P. 2013. Bioengineered concrete-a sustainable self-healing construction material, Research journal of engineering sciences ISSN, 2278 (2013) 9472.
Rautaray D, Ahmad A, Sastry M. 2003. Biosynthesis of CaCO3 crystals of complex morphology using a fungus and an actinomycete. J. Am. Chem. Soc. 125: 14656–14657.
Rautaray D, Ahmad A, Sastry M. 2004. Biological synthesis of metal carbonate minerals using fungi and actinomycetes. J. Mater. Chem. 14: 2333–2340.
Sayer JA, Kierans M, Gadd GM. 1997. Solubilisation of some naturally occurring metal-bearing minerals, limescale and lead phosphate by Aspergillus niger, FEMS Microbiol. Lett. 154: 29–35.
Seifan M, Samani A, Berenjian A. 2016. Bioconcrete: next generation of self-healing concrete. Appl. Microbiol. Biotechnol. 100: 2591–2602.
Setlow P. 1994. Mechanisms which contribute to the long?term survival of spores of Bacillus species, Journal of Applied Bacteriology 76: 49S-60S.
Sheir DH, Amer O, Elkhateeb WA, Daba GM. 2020. Elucidation of Myco-deterioration affecting Calcareous Construction Materials of the Egyptian Architectural Heritage. Boreal environment research 25: 27-56.
Ter Heide N, Schlangen E. 2007. Self-healing of early age cracks in concrete, First international conference on self healing materials 1-12.
Ter Heide N. 2005. Crack healing in hydrating concrete, Delft University of Technology 12-82.
Verrecchia EP. 2000. Fungi and sediments, in: R.E. Riding, S.M. Awramik (Eds.), Microbial Sediments, Springer-Verlag, Berlin 2000.
Vijay K, Murmu M. Deo S. 2017. Bacteria based self healing concrete–A review, Construction and Building Materials 152: 1008-1014.
Wang JY, De Belie N, Verstraete W. 2012. Diatomaceous earth as a protective vehicle for bacteria applied for self-healing concrete. J. Ind. Microbiol. Biotechnol. 39: 567–577.
Yang Y, Ma L, Huang J, Gu C, Xu Z, Liu J, Ni T. 2019. Evaluation of the thermal and shrinkage stresses in restrained high-performance concrete, Materials 12(2019): 3680.
Yang G, Gu C, Bao T, Cui Z, Kan K. 2016. Research on early-warning index of the spatial temperature field in concrete dams, SpringerPlus 5(2016): 1968.
Zhang J, Liu Y, Feng T, Zhou M, Zhao L, Zhou A. 2017. Immobilizing bacteria in expanded perlite for the crack self-healing in concrete. Constr. Build. Mater. 148: 610–617.
Zhang X. Qian C. 2020. Engineering Application of Microbial Self-healing Concrete in Lock Channel Wall, Case Studies in Construction Materials, (2020) e00398.
Zhu T, Dittrich M. 2016. Carbonate precipitation through microbial activities in natural environment, and their potential in biotechnology: a review. Frontiers in bioengineering and biotechnology 4: 4-25.