Mitchell J K, Santamarina J C. Biological considerations in geotechnical engineering. Journal of Geotechnical and Geoenvironmental Engineering, 2005, 131( 10): 1222– 1233

National Research Council. Geological and Geotechnical Engineering in the New Millennium: Opportunities for Research and Technological Innovation. Washington, D.C.: National Academies Press, 2006

DeJong J T, Soga K, Kavazanjian E, Burns S, Van Paassen L A, Al Qabany A, Aydilek A, Bang S S, Burbank M, Caslake L F, Chen C Y, Cheng X, Chu J, Ciurli S, Esnault-Filet A, Fauriel S, Hamdan N, Hata T, Inagaki Y, Jefferis S, Kuo M, Laloui L, Larrahondo J, Manning D A C, Martinez B, Montoya B M, Nelson D C, Palomino A, Renforth P, Santamarina J C, Seagren E A, Tanyu B, Tsesarsky M, Weaver T. Biogeochemical processes and geotechnical applications: Progress, opportunities and challenges. Geotechnique, 2013, 63( 4): 287– 301

Ivanov V, Chu J. Applications of microorganisms to geotechnical engineering for bioclogging and biocementation of soil in situ. Reviews in Environmental Science and Biotechnology, 2008, 7( 2): 139– 153

Dhami N K, Reddy M S, Mukherjee A. Biomineralization of calcium carbonates and their engineered applications: A review. Frontiers in Microbiology, 2013, 4 : 314–

Jiang N J, Tang C S, Hata T, Courcelles B, Dawoud O, Singh D N. Bio-mediated soil improvement: the way forward. Soil Use and Management, 2020, 36( 2): 185– 188

Martinez B C, DeJong J T. Bio-mediated soil improvement: load transfer mechanisms at the micro-and macro-scales. In: Proceedings of the US-China Workshop on Ground Improvement Technology. 2009, 242–251

Phillips A J, Gerlach R, Lauchnor E, Mitchell A C, Cunningham A B, Spangler L. Engineered applications of ureolytic biomineralization: A review. Biofouling, 2013, 29( 6): 715– 733

Terzis D, Laloui L. A decade of progress and turning points in the understanding of bio-improved soils: A review. Geomechanics for Energy and the Environment, 2019, 19 : 100116–

Baveye P, Vandevivere P, Hoyle B L, DeLeo P C, de Lozada D S. Environmental impact and mechanisms of the biological clogging of saturated soils and aquifer materials. Critical Reviews in Environmental Science and Technology, 1998, 28( 2): 123– 191

DeJong J, Proto C, Kuo M, Gomez M. Bacteria, biofilms, and invertebrates: The next generation of geotechnical engineers? In: Proceedings of the 2014 Geo-Congress. Atlanta: American Society of Civil Engineers, 2014, 3959–3968

He J, Chu J, Ivanov V. Mitigation of liquefaction of saturated sand using biogas. Geotechnique, 2013, 63( 4): 267– 275

O’Donnell S T, Rittmann B E, Kavazanjian E Jr. MIDP: Liquefaction mitigation via microbial denitrification as a two-stage process. I: Desaturation. Journal of Geotechnical and Geoenvironmental Engineering, 2017, 143( 12): 04017094–

DeJong J T, Fritzges M B, Nüsslein K. Microbially induced cementation to control sand response to undrained shear. Journal of Geotechnical and Geoenvironmental Engineering, 2006, 132( 11): 1381– 1392

van Paassen L A, Daza C M, Staal M, Sorokin D Y, van der Zon W, van Loosdrecht M C M. Potential soil reinforcement by biological denitrification. Ecological Engineering, 2010, 36( 2): 168– 175

Warthmann R, Van Lith Y, Vasconcelos C, McKenzie J A, Karpoff A M. Bacterially induced dolomite precipitation in anoxic culture experiments. Geology, 2000, 28( 12): 1091– 1094

Ivanov V, Chu J, Stabnikov V. Iron- and calcium-based biogrouts for porous soils. Proceedings of the Institution of Civil Engineers-Construction Materials, 2014, 167( 1): 36– 41

Roden E E, Urrutia M M. Influence of biogenic Fe (II) on bacterial crystalline Fe (III) oxide reduction. Geomicrobiology Journal, 2002, 19( 2): 209– 251

Yu X, Jiang J. Mineralization and cementing properties of bio-carbonate cement, bio-phosphate cement, and bio-carbonate/phosphate cement: a review. Environmental Science and Pollution Research International, 2018, 25( 22): 21483– 21497

Beato C, Fernández M S, Fermani S, Reggi M, Neira-Carrillo A, Rao A, Falini G, Arias J L. Calcium carbonate crystallization in tailored constrained environments. CrystEngComm, 2015, 17( 31): 5953– 5961

Wang Y Z, Soga K, DeJong J T, Kabla A J. A microfluidic chip and its use in characterising the particle-scale behaviour of microbial-induced calcium carbonate precipitation (MICP). Geotechnique, 2019, 69( 12): 1086– 1094

Wang Y, Soga K, DeJong J T, Kabla A J. Microscale visualization of microbial-induced calcium carbonate precipitation processes. Journal of Geotechnical and Geoenvironmental Engineering, 2019, 145( 9): 04019045–

Dupraz S, Parmentier M, Ménez B, Guyot F. Experimental and numerical modeling of bacterially induced pH increase and calcite precipitation in saline aquifers. Chemical Geology, 2009, 265( 1−2): 44– 53

Ghosh T, Bhaduri S, Montemagno C, Kumar A. Sporosarcina pasteurii can form nanoscale calcium carbonate crystals on cell surface. PLoS One, 2019, 14( 1): e0210339–

Hammes F, Boon N, de Villiers J, Verstraete W, Siciliano S D. Strain-specific ureolytic microbial calcium carbonate precipitation. Applied and Environmental Microbiology, 2003, 69( 8): 4901– 4909

Stocks-Fischer S, Galinat J K, Bang S S. Microbiological precipitation of CaCO ₃. Soil Biology & Biochemistry, 1999, 31( 11): 1563– 1571

Jimenez-Lopez C, Jroundi F, Rodríguez-Gallego M, Arias J M, Gonzalez-Muñoz M T. Biomineralization induced by Myxobacteria. Communicating Current Eesearch and Educational Ropics and Trends in Applied Microbiology, 2007, 1 : 143– 154

Gleaton J, Lai Z, Xiao R, Chen Q, Zheng Y. Microalga-induced biocementation of martian regolith simulant: Effects of biogrouting methods and calcium sources. Construction & Building Materials, 2019, 229 : 116885–

Bachmeier K L, Williams A E, Warmington J R, Bang S S. Urease activity in microbiologically-induced calcite precipitation. Journal of Biotechnology, 2002, 93( 2): 171– 181

Sharma M, Satyam N, Reddy K R. Rock-like behavior of biocemented sand treated under non-sterile environment and various treatment conditions. Journal of Rock Mechanics and Geotechnical Engineering, 2021, 13( 3): 705– 716

Whitaker J M, Vanapalli S, Fortin D. Improving the strength of sandy soils via ureolytic CaCO ₃ solidification by Sporosarcina ureae. Biogeosciences, 2018, 15( 14): 4367– 4380

Al-Thawadi S, Cord-Ruwisch R. Calcium carbonate crystals formation by ureolytic bacteria isolated from Australian soil and sludge. Journal of Advanced Science and Engineering Research, 2012, 2( 1): 12– 26

Amarakoon G G N N, Kawasaki S. Factors affecting sand solidification using MICP with Pararhodobacter sp. Materials Transactions, 2018, 59( 1): 72– 81

Arunachalam K D, Sathyanarayanan K S, Darshan B S, Raja R B. Studies on the characterisation of Biosealant properties of Bacillus sphaericus. International Journal of Engineering Science and Technology, 2010, 2( 3): 270– 277

Badiee H, Sabermahani M, Tabandeh F, Saeedi Javadi A. Application of an indigenous bacterium in comparison with Sporosarcina pasteurii for improvement of fine granular soil. International Journal of Environmental Science and Technology, 2019, 16( 12): 8389– 8400

Charpe A U, Latkar M V. Effect of biocementation using soil bacteria to augment the mechanical properties of cementitious materials. Materials Today: Proceedings, 2020, 21 : 1218– 1222

Chu J, Stabnikov V, Ivanov V. Microbially induced calcium carbonate precipitation on surface or in the bulk of soil. Geomicrobiology Journal, 2012, 29( 6): 544– 549

Danjo T, Kawasaki S. Microbially induced sand cementation method using Pararhodobacter sp. strain SO1, inspired by beachrock formation mechanism. Materials Transactions, 2016, 57( 3): 428– 437

Ghosh P, Mandal S, Pal S, Bandyopadhyaya G, Chattopadhyay B D. Development of bioconcrete material using an enrichment culture of novel thermophilic anaerobic bacteria. Indian Journal of Experimental Biology, 2006, 44 : 336– 339

Nemati M, Greene E A, Voordouw G. Permeability profile modification using bacterially formed calcium carbonate: Comparison with enzymic option. Process Biochemistry, 2005, 40( 2): 925– 933

Tsesarsky M, Gat D, Ronen Z. Biological aspects of microbial-induced calcite precipitation. Environmental Geotechnics, 2018, 5( 2): 69– 78

Umar M, Kassim K A, Zango M U, Muhammed A S. Performance evaluation of lime and microbial cementation in residual soil improvement. IOP Conference Series: Materials Science and Engineering, 2019, 527( 1): 012005–

Yang Z, Cheng X. A performance study of high-strength microbial mortar produced by low pressure grouting for the reinforcement of deteriorated masonry structures. Construction & Building Materials, 2013, 41 : 505– 515

Fujita Y, Ferris F G, Lawson R D, Colwell F S, Smith R W. Calcium carbonate precipitation by ureolytic subsurface bacteria. Geomicrobiology Journal, 2000, 17( 4): 305– 318

Cheng L, Cord-Ruwisch R. Selective enrichment and production of highly urease active bacteria by non-sterile (open) chemostat culture. Journal of Industrial Microbiology & Biotechnology, 2013, 40( 10): 1095– 1104

Yang Y, Chu J, Cao B, Liu H, Cheng L. Biocementation of soil using non-sterile enriched urease-producing bacteria from activated sludge. Journal of Cleaner Production, 2020, 262 : 121315–

Amini Kiasari M, Pakbaz M S, Ghezelbash G R. Increasing of soil urease activity by stimulation of indigenous bacteria and investigation of their role on shear strength. Geomicrobiology Journal, 2018, 35( 10): 821– 828

Burbank M, Weaver T, Lewis R, Williams T, Williams B, Crawford R. Geotechnical tests of sands following bioinduced calcite precipitation catalyzed by indigenous bacteria. Journal of Geotechnical and Geoenvironmental Engineering, 2013, 139( 6): 928– 936

Gat D, Ronen Z, Tsesarsky M. Soil bacteria population dynamics following stimulation for ureolytic microbial-induced CaCO ₃ precipitation. Environmental Science & Technology, 2016, 50( 2): 616– 624

Gat D, Ronen Z, Tsesarsky M. Long-term sustainability of microbial-induced CaCO ₃ precipitation in aqueous media. Chemosphere, 2017, 184 : 524– 531

Gomez M G, Graddy C M R, DeJong J T, Nelson D C, Tsesarsky M. Stimulation of native microorganisms for biocementation in samples recovered from field-scale treatment depths. Journal of Geotechnical and Geoenvironmental Engineering, 2018, 144( 1): 04017098–

Islam M T, Chittoori B C S, Burbank M. Evaluating the applicability of biostimulated calcium carbonate precipitation to stabilize clayey soils. Journal of Materials in Civil Engineering, 2020, 32( 3): 04019369–

Kannan K, Bindu J, Vinod P. Engineering behaviour of MICP treated marine clays. Marine Georesources and Geotechnology, 2020, 38( 7): 761– 769

Liu P, Shao G, Huang R. Study of the interactions between S. pasteurii and indigenous bacteria and the effect of these interactions on the MICP. Arabian Journal of Geosciences, 2019, 12( 23): 724–

Ramachandran A L, Polat P, Mukherjee A, Dhami N K. Understanding and creating biocementing beachrocks via biostimulation of indigenous microbial communities. Applied Microbiology and Biotechnology, 2020, 104( 8): 3655– 3673

Wang Y J, Han X L, Jiang N J, Wang J, Feng J. The effect of enrichment media on the stimulation of native ureolytic bacteria in calcareous sand. International Journal of Environmental Science and Technology, 2020, 17( 3): 1795– 1808

Chu J, Ivanov V, He J, Naeimi M, Li B, Stabnikov V. Development of microbial geotechnology in Singapore. In: Proceedings of Geo-Frontiers 2011 Advances in Geotechnical Engineering. Dallas: ASCE, 2011, 4070–4078

Chu J, Ivanov V, He J, Maeimi M, Wu S. Use of Biogeotechnologies for Soil Improvement. Ground Improvement Case Histories. Oxford: Butterworth-Heinemann, 2015, 571–589

DeJong J T, Mortensen B M, Martinez B C, Nelson D C. Bio-mediated soil improvement. Ecological Engineering, 2010, 36( 2): 197– 210

DeJong J T, Soga K, Banwart S A, Whalley W R, Ginn T R, Nelson D C, Mortensen B M, Martinez B C, Barkouki T. Soil engineering in vivo: Harnessing natural biogeochemical systems for sustainable, multi-functional engineering solutions. Journal of the Royal Society, Interface, 2011, 8( 54): 1– 15

Haouzi F Z, Courcelles B. Major applications of MICP sand treatment at multi-scale levels: A review. In: Proceedings of 71st Canadian Geotechnical Conference and 13th Joint CGS/IAH-CNC Groundwater Conference. Richmond: Canadian Geotechnical Society, 2018

Chae S H, Chung H, Nam K. Evaluation of microbially Induced calcite precipitation (MICP) methods on different soil types for wind erosion control. Environmental Engineering Research, 2021, 26( 1): 190507–

Jiang N J, Soga K, Kuo M. Microbially induced carbonate precipitation for seepage-induced internal erosion control in sand–clay mixtures. Journal of Geotechnical and Geoenvironmental Engineering, 2017, 143( 3): 04016100–

Jiang N J, Tang C S, Yin L Y, Xie Y H, Shi B. Applicability of microbial calcification method for sandy-slope surface erosion control. Journal of Materials in Civil Engineering, 2019, 31( 11): 04019250–

Jiang N J, Soga K. Erosional behavior of gravel-sand mixtures stabilized by microbially induced calcite precipitation (MICP). Soil and Foundation, 2019, 59( 3): 699– 709

Liu S, Wang R, Yu J, Peng X, Cai Y, Tu B. Effectiveness of the anti-erosion of an MICP coating on the surfaces of ancient clay roof tiles. Construction & Building Materials, 2020, 243 : 118202–

Maleki M, Ebrahimi S, Asadzadeh F, Emami Tabrizi M. Performance of microbial-induced carbonate precipitation on wind erosion control of sandy soil. International Journal of Environmental Science and Technology, 2016, 13( 3): 937– 944

Salifu E, MacLachlan E, Iyer K R, Knapp C W, Tarantino A. Application of microbially induced calcite precipitation in erosion mitigation and stabilisation of sandy soil foreshore slopes: A preliminary investigation. Engineering Geology, 2016, 201 : 96– 105

Van der Ruyt M, van der Zon W. Biological in situ reinforcement of sand in near-shore areas. Proceedings of the Institution of Civil Engineers-Geotechnical Engineering, 2009, 162( 1): 81– 83

Gerbersdorf S U, Jancke T, Westrich B, Paterson D M. Microbial stabilization of riverine sediments by extracellular polymeric substances. Geobiology, 2008, 6( 1): 57– 69

Bang S C, Min S H, Bang S S. KGS Awards Lectures: Application of microbiologically induced soil stabilization technique for dust suppression. International Journal of Geo-Engineering, 2011, 3( 2): 27– 37

Meyer F D, Bang S, Min S, Stetler L D, Bang S S. Microbiologically-induced soil stabilization: Application of Sporosarcina pasteurii for fugitive dust control. In: Proceedings of Geo-Frontiers 2011. Dallas: American Society of Civil Engineers, 2011, 4002–4011

Naeimi M, Chu J. Comparison of conventional and bio-treated methods as dust suppressants. Environmental Science and Pollution Research International, 2017, 24( 29): 23341– 23350

Stabnikov V, Naeimi M, Ivanov V, Chu J. Formation of water-impermeable crust on sand surface using biocement. Cement and Concrete Research, 2011, 41( 11): 1143– 1149

Stabnikov V, Chu J, Myo A N, Ivanov V. Immobilization of sand dust and associated pollutants using bioaggregation. Water, Air, and Soil Pollution, 2013, 224( 9): 1631–

Abo-El-Enein S A, Ali A H, Talkhan F N, Abdel-Gawwad H A. Utilization of microbial induced calcite precipitation for sand consolidation and mortar crack remediation. HBRC Journal, 2012, 8( 3): 185– 192

Achal V, Mukerjee A, Sudhakara Reddy M. Biogenic treatment improves the durability and remediates the cracks of concrete structures. Construction & Building Materials, 2013, 48 : 1– 5

Van Tittelboom K, De Belie N, De Muynck W, Verstraete W. Use of bacteria to repair cracks in concrete. Cement and Concrete Research, 2010, 40( 1): 157– 166

Yang Z, Cheng X, Li M. Engineering properties of MICP-bonded sandstones used for historical masonry building restoration. In: Proceedings of Geo-Frontiers 2011. Dallas: American Society of Civil Engineers, 2011, 4031–4040

De Muynck W, De Belie N, Verstraete W. Microbial carbonate precipitation in construction materials: A review. Ecological Engineering, 2010, 36( 2): 118– 136

De Muynck W, Verbeken K, De Belie N, Verstraete W. Influence of urea and calcium dosage on the effectiveness of bacterially induced carbonate precipitation on limestone. Ecological Engineering, 2010, 36( 2): 99– 111

De Muynck W, Leuridan S, Van Loo D, Verbeken K, Cnudde V, De Belie N, Verstraete W. Influence of pore structure on the effectiveness of a biogenic carbonate surface treatment for limestone conservation. Applied and Environmental Microbiology, 2011, 77( 19): 6808– 6820

De Muynck W, Verbeken K, De Belie N, Verstraete W. Influence of temperature on the effectiveness of a biogenic carbonate surface treatment for limestone conservation. Applied Microbiology and Biotechnology, 2013, 97( 3): 1335– 1347

Rodriguez-Navarro C, Rodriguez-Gallego M, Ben Chekroun K, Gonzalez-Munoz M T. Conservation of ornamental stone by Myxococcus xanthus-induced carbonate biomineralization. Applied and Environmental Microbiology, 2003, 69( 4): 2182– 2193

Cheng L, Shahin M A, Mujah D. Influence of key environmental conditions on microbially induced cementation for soil stabilization. Journal of Geotechnical and Geoenvironmental Engineering, 2017, 143( 1): 04016083–

Sharma M, Satyam N, Reddy K R. Effect of freeze−thaw cycles on engineering properties of biocemented sand under different treatment conditions. Engineering Geology, 2021, 284 : 106022–

Abbasi B, Ta H X, Muhunthan B, Ramezanian S, Abu-Lail N, Kwon T H. Modeling of Permeability Reduction in Bioclogged Porous Sediments. Journal of Geotechnical and Geoenvironmental Engineering, 2018, 144( 4): 04018016–

Flemming H C, Wingender J. The biofilm matrix. Nature Reviews. Microbiology, 2010, 8( 9): 623– 633

Ng C W W, So P S, Coo J L, Zhou C, Lau S Y. Effects of biofilm on gas permeability of unsaturated sand. Geotechnique, 2019, 69( 10): 917– 923

Farah T, Souli H, Fleureau J M, Kermouche G, Fry J J, Girard B, Aelbrecht D, Lambert J, Harkes M. Durability of Bioclogging Treatment of Soils. Journal of Geotechnical and Geoenvironmental Engineering, 2016, 142( 9): 04016040–

Muthukkumaran K, Shashank B S. Durability of microbially induced calcite precipitation (micp) treated cohesionless soils. Japanese Geotechnical Society Special Publication, 2016, 2( 56): 1946– 1949

Jiang N J, Soga K. The applicability of microbially induced calcite precipitation (MICP) for internal erosion control in gravel-sand mixtures. Geotechnique, 2017, 67( 1): 42– 55

Clarà Saracho A, Haigh S K, Ehsan Jorat M. Flume study on the effects of microbial induced calcium carbonate precipitation (MICP) on the erosional behaviour of fine sand. Geotechnique, 2020: 1–15

Chu J, Ivanov V, Stabnikov V, Li B. Microbial method for construction of an aquaculture pond in sand. Geotechnique, 2013, 63( 10): 871– 875

Stabnikov V, Ivanov V, Chu J. Sealing of sand using spraying and percolating biogrouts for the construction of model aquaculture pond in arid desert. International Aquatic Research, 2016, 8( 3): 207– 216

Minto J M, MacLachlan E, El Mountassir G, Lunn R J. Rock fracture grouting with microbially induced carbonate precipitation. Water Resources Research, 2016, 52( 11): 8827– 8844

Wu C Z, Chu J, Wu S F, Hong Y. 3D characterization of microbially induced carbonate precipitation in rock fracture and the resulted permeability reduction. Engineering Geology, 2019, 249 : 23– 30

Wu C Z, Chu J, Wu S F, Cheng L, van Paassen L A. Microbially induced calcite precipitation along a circular flow channel under a constant flow condition. Acta Geotechnica, 2019, 14( 3): 673– 683

Wu C Z, Chu J, Wu S F, Guo W. Quantifying the permeability reduction of biogrouted rock fracture. Rock Mechanics and Rock Engineering, 2019, 52( 3): 947– 954

Wu S F, Chu J, Wu C Z. Biogrouting for Seepage Control for Rock Joints. In: ISRM International Symposium—10th Asian Rock Mechanics Symposium. Singapore: International Society for Rock Mechanics and Rock Engineering, 2018

Qian C X, Wang J Y, Wang R X, Cheng L. Corrosion protection of cement-based building materials by surface deposition of CaCO ₃ by Bacillus pasteurii. Materials Science and Engineering C, 2009, 29( 4): 1273– 1280

Gollapudi U K, Knutson C L, Bang S S, Islam M R. A new method for controlling leaching through permeable channels. Chemosphere, 1995, 30( 4): 695– 705

MacLeod F A, Lappin-Scott H M, Costerton J W. Plugging of a model rock system by using starved bacteria. Applied and Environmental Microbiology, 1988, 54( 6): 1365– 1372

Zhong L, Islam M. A new microbial plugging process and its impact on fracture remediation. In: SPE Annual Technical Conference and Exhibition. Dallas: Society of Petroleum Engineers, 1995

O’Donnell S T, Hall C A, Kavazanjian E Jr, Rittmann B E. Biogeochemical model for soil improvement by denitrification. Journal of Geotechnical and Geoenvironmental Engineering, 2019, 145( 11): 04019091–

O’Donnell S T, Rittmann B E, Kavazanjian E Jr. Factors controlling microbially induced desaturation and precipitation (MIDP) via denitrification during continuous flow. Geomicrobiology Journal, 2019, 36( 6): 543– 558

He J, Chu J, Wu S, Peng J. Mitigation of soil liquefaction using microbially induced desaturation. Journal of Zhejiang University. Science A, 2016, 17( 7): 577– 588

He J, Chu J, Gao Y, Liu H. Research advances and challenges in biogeotechnologies. Geotechnical Research, 2019, 6( 2): 144– 155

Carlson C A, Ingraham J L. Comparison of denitrification by Pseudomonas stutzeri, Pseudomonas aeruginosa, and Paracoccus denitrificans. Applied and Environmental Microbiology, 1983, 45( 4): 1247– 1253

Peng E X, Zhang D W. Prevention of liquefaction of saturated sand using biogas produced by Pseudomonas stutzeri. In: 2017 International Conference on Transportation Infrastructure and Materials (ICTIM 2017). Qingdao: DEStech Transactions on Materials Science and Engineering, 2017

O’Donnell S T, Kavazanjian E Jr, Rittmann B E. MIDP: Liquefaction mitigation via microbial denitrification as a two-stage process. II: MICP. Journal of Geotechnical and Geoenvironmental Engineering, 2017, 143( 12): 04017095–

Saggar S, Jha N, Deslippe J, Bolan N, Luo J, Giltrap D, Kim D G, Zaman M, Tillman R. Denitrification and N ₂O: N ₂ production in temperate grasslands: Processes, measurements, modelling and mitigating negative impacts. Science of the Total Environment, 2013, 465 : 173– 195

Chou C, Seagren E, Aydilek A, Lai M. Biocalcification of sand through ureolysis. Journal of Geotechnical and Geoenvironmental Engineering, 2011, 137( 12): 1179– 1189

Do J, Montoya B M, Gabr M A. Debonding of microbially induced carbonate precipitation-stabilized sand by shearing and erosion. Geomechanics and Engineering. International Journal (Toronto, Ont.), 2019, 17( 5): 429– 438

Feng K, Montoya B. Influence of confinement and cementation level on the behavior of microbial-induced calcite precipitated sands under monotonic drained loading. Journal of Geotechnical and Geoenvironmental Engineering, 2016, 142( 1): 04015057–

Feng Z, Zhao Y, Zeng W, Lu Z, Shah S P. Using microbial carbonate precipitation to improve the properties of recycled fine aggregate and mortar. Construction & Building Materials, 2020, 230 : 116949–

Gai X, Sánchez M. An elastoplastic mechanical constitutive model for microbially mediated cemented soils. Acta Geotechnica, 2019, 14( 3): 709– 726

Liu L, Liu H, Stuedlein A W, Evans T M, Xiao Y. Strength, stiffness, and microstructure characteristics of biocemented calcareous sand. Canadian Geotechnical Journal, 2019, 56( 10): 1502– 1513

Nafisi A, Mocelin D, Montoya B M, Underwood S. Tensile strength of sands treated with microbially induced carbonate precipitation. Canadian Geotechnical Journal, 2020, 57( 10): 1611– 1616

Shanahan C, Montoya B M. Strengthening coastal sand dunes using microbial-induced calcite precipitation. In: Proceedings of the 2014 Geo-Congress. Atlanta: American Society of Civil Engineers, 2014: 1683–1692

Sharma A, Ramkrishnan R. Study on effect of microbial induced calcite precipitates on strength of fine grained soils. Perspectives in Science, 2016, 8 : 198– 202

Thomas O’Donnell S, Kavazanjian E Jr. Stiffness and dilatancy improvements in uncemented sands treated through MICP. Journal of Geotechnical and Geoenvironmental Engineering, 2015, 141( 11): 02815004–

Bernardi D, DeJong J T, Montoya B M, Martinez B C. Bio-bricks: Biologically cemented sandstone bricks. Construction & Building Materials, 2014, 55 : 462– 469

Choi S G, Wu S, Chu J. Biocementation for sand using an eggshell as calcium source. Journal of Geotechnical and Geoenvironmental Engineering, 2016, 142( 10): 06016010–

Choi S G, Wang K, Chu J. Properties of biocemented, fiber reinforced sand. Construction & Building Materials, 2016, 120 : 623– 629

Choi S G, Chu J, Brown R C, Wang K, Wen Z. 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, 2017, 5( 6): 5183– 5190

Chu J, Ivanov V, Naeimi M, Stabnikov V, Liu H L. Optimization of calcium-based bioclogging and biocementation of sand. Acta Geotechnica, 2014, 9( 2): 277– 285

He J, Chu J. Cementation of sand due to salt precipitation in drying process. Marine Georesources and Geotechnology, 2017, 35( 3): 441– 445

Lee M L, Ng W S, Tanaka Y. Stress-deformation and compressibility responses of bio-mediated residual soils. Ecological Engineering, 2013, 60 : 142– 149

Waldschmidt J B, Courcelles B. Influence of resting periods on the efficiency of microbially induced calcite precipitation (MICP) in non-saturated conditions. In: International Congress and Exhibition “Sustainable Civil Infrastructures”. Springer, Cham, 2019, 119–126

Xiao Y, Yuan Z, Lin J, Ran J, Dai B, Chu J, Liu H. Effect of particle shape of glass beads on the strength and deformation of cemented sands. Acta Geotechnica, 2019, 14( 6): 2123– 2131

Xiao Y, Wang Y, Desai C S, Jiang X, Liu H. Strength and deformation responses of biocemented sands using a temperature-controlled method. International Journal of Geomechanics, 2019, 19( 11): 04019120–

Venuleo S, Laloui L, Terzis D, Hueckel T, Hassan M. Microbially induced calcite precipitation effect on soil thermal conductivity. Géotechnique Letters, 2016, 6( 1): 39– 44

Wang Z, Zhang N, Ding J, Li Q, Xu J. Thermal conductivity of sands treated with microbially induced calcite precipitation (MICP) and model prediction. International Journal of Heat and Mass Transfer, 2020, 147 : 118899–

Choi S G, Hoang T, Alleman E J, Chu J. Splitting tensile strength of fiber-reinforced and biocemented sand. Journal of Materials in Civil Engineering, 2019, 31( 9): 06019007–

Choi S G, Hoang T, Park S S. Undrained behavior of microbially induced calcite precipitated sand with polyvinyl alcohol fiber. Applied Sciences (Basel, Switzerland), 2019, 9( 6): 1214–

Lei X W, Lin S Q, Meng Q S, Liao X, Xu J. Influence of different fiber types on properties of biocemented calcareous sand. Arabian Journal of Geosciences, 2020, 13( 8): 317–

Li M, Li L, Ogbonnaya U, Wen K, Tian A, Amini F. Influence of fiber addition on mechanical properties of MICP-treated sand. Journal of Materials in Civil Engineering, 2016, 28( 4): 04015166–

Li L, Li M, Ogbonnaya U, Wen K, Xu Y, Amini F. Study of a discrete randomly distributed fiber on the tensile strength improvement of microbial-induced soil stabilization. In: Geotechnical Frontiers 2017. Orlando: American Society of Civil Engineers, 2017, 12–18

Liu S, Wen K, Armwood C, Bu C, Li C, Amini F, Li L. Enhancement of MICP-treated sandy soils against environmental deterioration. Journal of Materials in Civil Engineering, 2019, 31( 12): 04019294–

Xiao Y, He X, Evans T M, Stuedlein A W, Liu H. Unconfined compressive and splitting tensile strength of basalt fiber–reinforced biocemented sand. Journal of Geotechnical and Geoenvironmental Engineering, 2019, 145( 9): 04019048–

Yao D F, Wu J, Wang G W, Wang P B, Zheng J J, Yan J Y, Xu L, Yan Y J. Effect of wool fiber addition on the reinforcement of loose sands by microbially induced carbonate precipitation (MICP): Mechanical property and underlying mechanism. Acta Geotechnica, 2021, 16( 5): 1401– 1416

Zhao Y, Fan C, Ge F, Cheng X, Liu P. Enhancing strength of MICP-treated sand with scrap of activated carbon-fiber felt. Journal of Materials in Civil Engineering, 2020, 32( 4): 04020061–

Hamdan N, Zhao Z, Mujica M, Kavazanjian E Jr, He X. Hydrogel-assisted enzyme-induced carbonate mineral precipitation. Journal of Materials in Civil Engineering, 2016, 28( 10): 04016089–

Wang X R, Tao J L, Bao R T, Tran T, Tucker-Kulesza S. Surficial soil stabilization against water-induced erosion using polymer-modified microbially induced carbonate precipitation. Journal of Materials in Civil Engineering, 2018, 30( 10): 04018267–

Wang X R, Tao J L. Polymer-modified microbially induced carbonate precipitation for one-shot targeted and localized soil improvement. Acta Geotechnica, 2019, 14( 3): 657– 671

Cheng L, Yang Y, Chu J. In-situ microbially induced Ca ²⁺-alginate polymeric sealant for seepage control in porous materials. Microbial Biotechnology, 2019, 12( 2): 324– 333

Ivanov V, Chu J, Stabnikov V, Li B. Strengthening of soft marine clay using bioencapsulation. Marine Georesources and Geotechnology, 2015, 33( 4): 320– 324

Liu B, Zhu C, Tang C S, Xie Y H, Yin L Y, Cheng Q, Shi B. Bio-remediation of desiccation cracking in clayey soils through microbially induced calcite precipitation (MICP). Engineering Geology, 2020, 264 : 105389–

Rebata-Landa V. Microbial activity in sediments: Effects on soil behavior. Dissertation for the Doctoral Degree. Atlanta: Georgia Institute of Technology, 2007

Kim D, Park K, Kim D. Effects of ground conditions on microbial cementation in soils. Materials (Basel), 2013, 7( 1): 143– 156

Lee M L, Ng W S, Tan C K, Hii S L. Bio-mediated soil improvement under various concentrations of cementation reagent. Applied Mechanics and Materials, 2012, 204 : 326– 329

Ng W S, Lee M L, Hii S L. An overview of the factors affecting microbial-induced calcite precipitation and its potential application in soil improvement. World Academy of Science, Engineering and Technology, 2012, 62( 2): 723– 729

Soon N W, Lee L M, Khun T C, Ling H S. Improvements in engineering properties of soils through microbial-induced calcite precipitation. KSCE Journal of Civil Engineering, 2013, 17( 4): 718– 728

Soon N W, Lee L M, Khun T C, Ling H S. Factors affecting improvement in engineering properties of residual soil through microbial-induced calcite precipitation. Journal of Geotechnical and Geoenvironmental Engineering, 2014, 140( 5): 04014006–

Safavizadeh S, Montoya B M, Gabr M A. Effect of Microbial Induced Calcium Carbonate Precipitation on the Performance of Ponded Coal Ash. Kentucky: Association of State Dam Safety Officials, Inc., 2017

Zhang J, Wen K, Li L. Leaching assessment of MICP-treated coal combustion products in roadways embankment. In: Eighth International Conference on Case Histories in Geotechnical Engineering (Geo-Congress 2019). Philadelphia: American Society of Civil Engineers, 2019

Chittoori B C S, Rahman T, Burbank M, Moghal A A B. Evaluating shallow mixing protocols as application methods for microbial induced calcite precipitation targeting expansive soil treatment. In: Eighth International Conference on Case Histories in Geotechnical Engineering. Philadelphia: American Society of Civil Engineers, 2019

Liu S, Yu J, Peng X, Cai Y, Tu B. Preliminary study on repairing tabia cracks by using microbially induced carbonate precipitation. Construction & Building Materials, 2020, 248 : 118611–

Cardoso R, Pires I, Duarte S O D, Monteiro G A. Effects of clay’s chemical interactions on biocementation. Applied Clay Science, 2018, 156 : 96– 103

Sasaki T, Kuwano R. Undrained cyclic triaxial testing on sand with non-plastic fines content cemented with microbially induced CaCO ₃. Soil and Foundation, 2016, 56( 3): 485– 495

Sun X, Miao L, Chen R. Effects of different clay’s percentages on improvement of sand-clay mixtures with microbially induced calcite precipitation. Geomicrobiology Journal, 2019, 36( 9): 810– 818

Hoang T, Alleman J, Cetin B, Ikuma K, Choi S G. Sand and silty-sand soil stabilization using bacterial enzyme-induced calcite precipitation (BEICP). Canadian Geotechnical Journal, 2019, 56( 6): 808– 822

Ibrahim M A, Al-Omari R R, Ibrahim M H. Experimental study to improve the shear stress of silty-sandy soils by using urease producing bacteria. American Scientific Research Journal for Engineering, Technology, and Sciences, 2018, 41( 1): 271– 277 (ASRJETS)

Zamani A, Montoya B M. Undrained monotonic shear response of MICP-treated silty sands. Journal of Geotechnical and Geoenvironmental Engineering, 2018, 144( 6): 04018029–

Khamehchiyan M, Rowshanbakht K, Nikudel M R, Sajedi R H. Biological improvement of sandy soil by microbial induced carbonate precipitation. Journal of Kerbala University, 2015, 100– 110

Pakbaz M S, Behzadipour H, Ghezelbash G R. Evaluation of shear strength parameters of sandy soils upon microbial treatment. Geomicrobiology Journal, 2018, 35( 8): 721– 726

Hoang T, Alleman J, Cetin B, Choi S G. Engineering properties of biocementation coarse-and fine-grained sand catalyzed by bacterial cells and bacterial enzyme. Journal of Materials in Civil Engineering, 2020, 32( 4): 04020030–

Cui M J, Lai H J, Hoang T, Chu J. One-phase-low-pH enzyme induced carbonate precipitation (EICP) method for soil improvement. Acta Geotechnica, 2021, 16( 2): 481– 489

Mahawish A, Bouazza A, Gates W P. Improvement of coarse sand engineering properties by microbially induced calcite precipitation. Geomicrobiology Journal, 2018, 35( 10): 887– 897

Mahawish A, Bouazza A, Gates W P. Factors affecting the bio-cementing process of coarse sand. Proceedings of the Institution of Civil Engineers-Ground Improvement, 2019, 172( 1): 25– 36

Mahawish A, Bouazza A, Gates W P. Unconfined compressive strength and visualization of the microstructure of coarse sand subjected to different biocementation levels. Journal of Geotechnical and Geoenvironmental Engineering, 2019, 145( 8): 04019033–

Pan X, Chu J, Yang Y, Cheng L. A new biogrouting method for fine to coarse sand. Acta Geotechnica, 2020, 15( 1): 1– 16

Cui M J, Zheng J J, Chu J, Wu C C, Lai H J. Bio-mediated calcium carbonate precipitation and its effect on the shear behaviour of calcareous sand. Acta Geotechnica, 2021, 16( 5): 1377– 1389

Deng W, Wang Y. Investigating the factors affecting the properties of coral sand treated with microbially induced calcite precipitation. Advances in Civil Engineering, 2018, 2018 : 9590653–

Xiao P, Liu H, Stuedlein A W, Evans T M, Xiao Y. Effect of relative density and biocementation on cyclic response of calcareous sand. Canadian Geotechnical Journal, 2019, 56( 12): 1849– 1862

Xiao P, Liu H, Xiao Y, Stuedlein A W, Evans T M. Liquefaction resistance of bio-cemented calcareous sand. Soil Dynamics and Earthquake Engineering, 2018, 107 : 9– 19

Zhang X, Chen Y, Liu H, Zhang Z, Ding X. Performance evaluation of a MICP-treated calcareous sandy foundation using shake table tests. Soil Dynamics and Earthquake Engineering, 2020, 129 : 105959–

van der Star W R L, van Wijngaarden W K, van Paassen L A, van Baalen L R, Zwieten G. Stabilization of gravel deposits using microorganisms. In: Proceedings of the 15th European Conference on Soil Mechanics and Geotechnical Engineering. Athens: Millpress, 2011

van Paassen L A, Hemert W J, Star W R L, Zwieten G V, Baalen L V. Direct shear strength of biologically cemented gravel. In: Proceedings of GeoCongress 2012. Oakland: American Society of Civil Engineers, 2012, 968–977

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

Mahawish A, Bouazza A, Gates W P. Strengthening crushed coarse aggregates using bio-grouting. Geomechanics and Geoengineering, 2019, 14( 1): 59– 70

Wu C Z, Chu J, Cheng L, Wu S F. Biogrouting of aggregates using premixed injection method with or without pH adjustment. Journal of Materials in Civil Engineering, 2019, 31( 9): 06019008–

Gomez M G, DeJong J T. Engineering properties of bio-cementation improved sandy soils. In: Grouting 2017. Honolulu: American Society of Civil Engineers, 2017, 23–33

Phadnis H S, Santamarina J C. Bacteria in sediments: Pore size effects. Géotechnique Letters, 2011, 1( 4): 91– 93

Ma G, He X, Jiang X, Liu H, Chu J, Xiao Y. Strength and permeability of bentonite-assisted biocemented coarse sand. Canadian Geotechnical Journal, 2021, 58( 7): 969– 981

Wu C Z, Chu J. Biogrouting method for stronger bond strength for aggregates. Journal of Geotechnical and Geoenvironmental Engineering, 2020, 146( 11): 06020021–

Cheng L, Shahin M A. Urease active bioslurry: A novel soil improvement approach based on microbially induced carbonate precipitation. Canadian Geotechnical Journal, 2016, 53( 9): 1376– 1385

Amarakoon G G N N, Kawasaki S. Factors affecting the improvement of sand properties treated with microbially-induced calcite precipitation. In: Geo-Chicago 2016. Chicago: American Society of Civil Engineers, 2016, 72–83

Zhao Q, Li L, Li C, Li M, Amini F, Zhang H. Factors affecting improvement of engineering properties of MICP-treated soil catalyzed by bacteria and urease. Journal of Materials in Civil Engineering, 2014, 26( 12): 04014094–

Lin H, Suleiman M, Brown D, Kavazanjian E Jr. Mechanical behavior of sands treated by microbially induced carbonate precipitation. Journal of Geotechnical and Geoenvironmental Engineering, 2016, 142( 2): 04015066–

Terzis D, Laloui L. 3-D micro-architecture and mechanical response of soil cemented via microbial-induced calcite precipitation. Scientific Reports, 2018, 8( 1): 1416–

Terzis D, Laloui L. Cell-free soil bio-cementation with strength, dilatancy and fabric characterization. Acta Geotechnica, 2019, 14( 3): 639– 656

Dhami N K, Reddy M S, Mukherjee A. Significant indicators for biomineralisation in sand of varying grain sizes. Construction & Building Materials, 2016, 104 : 198– 207

Cheng L, Cord-Ruwisch R, Shahin M A. Cementation of sand soil by microbially induced calcite precipitation at various degrees of saturation. Canadian Geotechnical Journal, 2013, 50( 1): 81– 90

Eryürük K, Yang S, Suzuki D, Sakaguchi I, Akatsuka T, Tsuchiya T, Katayama A. Reducing hydraulic conductivity of porous media using CaCO ₃ precipitation induced by Sporosarcina pasteurii. Journal of Bioscience and Bioengineering, 2015, 119( 3): 331– 336

Cardoso R, Pedreira R, Duarte S O D, Monteiro G A. About calcium carbonate precipitation on sand biocementation. Engineering Geology, 2020, 271 : 105612–

Zamani A, Montoya B M, Gabr M A. Investigating challenges of in situ delivery of microbial-induced calcium carbonate precipitation (MICP) in fine-grain sands and silty sand. Canadian Geotechnical Journal, 2019, 56( 12): 1889– 1900

Tsukamoto M, Oda K. Influence of relative density on microbial carbonate precipitation and mechanical properties of sand. In: Proceedings of the 18th International Conference on Soil Mechanics and Geotechnical Engineering. Paris: Presses des Ponts, 2013, 2613–2616

Cheng L, Shahin M A, Cord-Ruwisch R, Addis M, Hartanto T, Elms C. Soil stabilisation by microbial-induced calcite precipitation (micp): Investigation into some physical and environmental aspects. In: 7th International Congress on Environmental Geotechnics: ICEG2014. Melbourne: Engineers Australia, 2014, 1105

Rowshanbakht K, Khamehchiyan M, Sajedi R H, Nikudel M R. Effect of injected bacterial suspension volume and relative density on carbonate precipitation resulting from microbial treatment. Ecological Engineering, 2016, 89 : 49– 55

Lakshmi S M, Mathura J, Gayathri U, Vedhanayaghi V J. Enhancement of shear strength characteristics by microbial cementation in sand. International Journal of Innovative Research Explorer, 2019, 5( 6): 1– 11

Song C, Elsworth D, Zhi S, Wang C. The influence of particle morphology on microbially induced CaCO ₃ clogging in granular media. Marine Georesources and Geotechnology, 2021, 39( 1): 74– 81

Gat D, Tsesarsky M, Wahanon A, Ronen Z. Ureolysis and MICP with model and native bacteria: Implications for treatment strategies. In: Proceedings of the 2014 Geo-Congress. Atlanta: American Society of Civil Engineers, 2014, 1713–1720

Hataf N, Baharifard A. Reducing soil permeability using microbial induced carbonate precipitation (MICP) method: A case study of shiraz landfill soil. Geomicrobiology Journal, 2020, 37( 2): 147– 158

Wen K, Li Y, Amini F, Li L. Impact of bacteria and urease concentration on precipitation kinetics and crystal morphology of calcium carbonate. Acta Geotechnica, 2020, 15( 1): 17– 27

Wang Y Z, Soga K, DeJong J T, Kabla A. Effects of bacterial density on growth rate and characteristics of microbial-induced CaCO3 precipitates: A particle-scale experimental study. Journal of Geotechnical and Geoenvironmental Engineering, 2021, 147( 6): 04021036–

Zhao Y, Fan C, Liu P, Fang H, Huang Z. Effect of activated carbon on microbial-induced calcium carbonate precipitation of sand. Environmental Earth Sciences, 2018, 77( 17): 615–

Omoregie A I, Palombo E A, Ong D E L, Nissom P M. A feasible scale-up production of Sporosarcina pasteurii using custom-built stirred tank reactor for in-situ soil biocementation. Biocatalysis and Agricultural Biotechnology, 2020, 24 : 101544–

Zhao Y, Xiao Z, Lv J, Shen W, Xu R. A novel approach to enhance the urease activity of Sporosarcina pasteurii and its application on microbial-induced calcium carbonate precipitation for sand. Geomicrobiology Journal, 2019, 36( 9): 819– 825

Achal V, Mukherjee A, Basu P C, Reddy M S. Strain improvement of Sporosarcina pasteurii for enhanced urease and calcite production. Journal of Industrial Microbiology & Biotechnology, 2009, 36( 7): 981– 988

Bu C, Wen K, Liu S, Ogbonnaya U, Li L. Development of bio-cemented constructional materials through microbial induced calcite precipitation. Materials and Structures, 2018, 51( 1): 30–

Inagaki Y, Tsukamoto M, Mori H, Sasaki T, Soga K, Al Qabany A, Hata T. The influence of injection conditions and soil types on soil improvement by microbial functions. In: Proceedings of Geo-Frontiers 2011. Dallas: American Society of Civil Engineers, 2011, 4021–4030

Li M, Wen K, Li Y, Zhu L. Impact of oxygen availability on microbially induced calcite precipitation (MICP) treatment. Geomicrobiology Journal, 2018, 35( 1): 15– 22

Mortensen B M, DeJong J T. Strength and stiffness of MICP treated sand subjected to various stress paths. In: Proceedings of Geo-Frontiers 2011. Dallas: American Society of Civil Engineers, 2011, 4012–4020

Park S S, Choi S G, Kim W J, Lee J C. Effect of microbially induced calcite precipitation on strength of cemented sand. New Frontiers in Geotechnical Engineering GSP, 2017, 243 : 47– 56

Terzis D, Bernier-Latmani R, Laloui L. Fabric characteristics and mechanical response of bio-improved sand to various treatment conditions. Géotechnique Letters, 2016, 6( 1): 50– 57

Chen H J, Huang Y H, Chen C C, Maity J P, Chen C Y. Microbial induced calcium carbonate precipitation (MICP) using pig urine as an alternative to industrial urea. Waste and Biomass Valorization, 2019, 10( 10): 2887– 2895

Achal V, Pan X. Influence of calcium sources on microbially induced calcium carbonate precipitation by Bacillus sp. CR2. Applied Biochemistry and Biotechnology, 2014, 173( 1): 307– 317

Gorospe C M, Han S H, Kim S G, Park J Y, Kang C H, Jeong J H, So J S. Effects of different calcium salts on calcium carbonate crystal formation by Sporosarcina pasteurii KCTC 3558. Biotechnology and Bioprocess Engineering; BBE, 2013, 18( 5): 903– 908

Zhang Y, Guo H X, Cheng X H. Role of calcium sources in the strength and microstructure of microbial mortar. Construction & Building Materials, 2015, 77 : 160– 167

Zhang Y, Guo H X, Cheng X H. Influences of calcium sources on microbially induced carbonate precipitation in porous media. Materials Research Innovations, 2014, 18( sup2): 79– 84

Cheng L, Shahin M A, Cord-Ruwisch R. Bio-cementation of sandy soil using microbially induced carbonate precipitation for marine environments. Geotechnique, 2014, 64( 12): 1010– 1013

Liang S, Chen J, Niu J, Gong X, Feng D. Using recycled calcium sources to solidify sandy soil through microbial induced carbonate precipitation. Marine Georesources and Geotechnology, 2020, 38( 4): 393– 399

Liu L, Liu H, Xiao Y, Chu J, Xiao P, Wang Y. Biocementation of calcareous sand using soluble calcium derived from calcareous sand. Bulletin of Engineering Geology and the Environment, 2018, 77( 4): 1781– 1791

Al Qabany A, Soga K. Effect of chemical treatment used in MICP on engineering properties of cemented soils. Geotechnique, 2013, 63( 4): 331– 339

Lai H J, Cui M J, Wu S F, Yang Y, Chu J. Retarding effect of concentration of cementation solution on biocementation of soil. Acta Geotechnica, 2021, 16( 5): 1457– 1472

Mujah D, Cheng L, Shahin M A. Microstructural and geomechanical study on biocemented sand for optimization of MICP process. Journal of Materials in Civil Engineering, 2019, 31( 4): 04019025–

Velpuri N V P, Yu X, Lee H I, Chang W S. Influence factors for microbial-induced calcite precipitation in sands. In: Geo-China 2016. Shandong: American Society of Civil Engineers, 2016, 44–52

Mori D, Jyoti P, Thakur T, Masakapalli S K, Uday K V. Influence of cementing solution concentration on calcite precipitation pattern in biocementation. In: Advances in Computer Methods and Geomechanics. Singapore: Springer, 2020, 737–746

Wen K, Li Y, Liu S, Bu C, Li L. Development of an improved immersing method to enhance microbial induced calcite precipitation treated sandy soil through multiple treatments in low cementation media concentration. Geotechnical and Geological Engineering, 2019, 37( 2): 1015– 1027

Li W, Chen W S, Zhou P P, Zhu S L, Yu L J. Influence of initial calcium ion concentration on the precipitation and crystal morphology of calcium carbonate induced by bacterial carbonic anhydrase. Chemical Engineering Journal, 2013, 218 : 65– 72

Okwadha G D O, Li J. Optimum conditions for microbial carbonate precipitation. Chemosphere, 2010, 81( 9): 1143– 1148

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

van Paassen L, Ghose R, van der Linden T, van der Star W, van Loosdrecht M. Quantifying biomediated ground improvement by ureolysis: Large-scale biogrout experiment. Journal of Geotechnical and Geoenvironmental Engineering, 2010, 136( 12): 1721– 1728

Whiffin V S, van Paassen L A, Harkes M P. Microbial carbonate precipitation as a soil improvement technique. Geomicrobiology Journal, 2007, 24( 5): 417– 423

Rong H, Qian C X, Li L. Study on microstructure and properties of sandstone cemented by microbe cement. Construction & Building Materials, 2012, 36 : 687– 694

Ghasemi P, Zamani A, Montoya B. The effect of chemical concentration on the strength and erodibility of MICP treated sands. In: Eighth International Conference on Case Histories in Geotechnical Engineering. Philadelphia: American Society of Civil Engineers, 2019, 241–249

Keykha H A, Asadi A, Zareian M. Environmental factors affecting the compressive strength of microbiologically induced calcite precipitation-treated soil. Geomicrobiology Journal, 2017, 34( 10): 889– 894

Li W, Chen W S, Zhou P P, Cao L, Yu L J. Influence of initial pH on the precipitation and crystal morphology of calcium carbonate induced by microbial carbonic anhydrase. Colloids and Surfaces. B, Biointerfaces, 2013, 102 : 281– 287

Seifan M, Samani A K, Berenjian A. New insights into the role of pH and aeration in the bacterial production of calcium carbonate (CaCO ₃). Applied Microbiology and Biotechnology, 2017, 101( 8): 3131– 3142

Martinez B C, Barkouki T H, DeJong J D, Ginn T R. Upscaling of microbial induced calcite precipitation in 0.5 m columns: experimental and modeling results. In: Proceedings of Geo-Frontiers 2011. Dallas: American Society of Civil Engineers, 2011: 4049–4059

Rong H, Qian C, Li L. Influence of molding process on mechanical properties of sandstone cemented by microbe cement. Construction & Building Materials, 2012, 28( 1): 238– 243

Al Qabany A, Mortensen B, Martinez B, Soga K, DeJong J. Microbial carbonate precipitation: correlation of S-wave velocity with calcite precipitation. In: Proceedings of Geo-Frontiers 2011. Dallas: American Society of Civil Engineers, 2011, 3993–4001

Cheng L, Cord-Ruwisch R. In situ soil cementation with ureolytic bacteria by surface percolation. Ecological Engineering, 2012, 42 : 64– 72

Cui M J, Zheng J J, Zhang R J, Lai H J, Zhang J. Influence of cementation level on the strength behaviour of bio-cemented sand. Acta Geotechnica, 2017, 12( 5): 971– 986

Harkes M P, van Paassen L A, Booster J L, Whiffin V S, van Loosdrecht M C M. Fixation and distribution of bacterial activity in sand to induce carbonate precipitation for ground reinforcement. Ecological Engineering, 2010, 36( 2): 112– 117

Tian Z F, Tang X, Xiu Z L, Xue Z J. Effect of different biological solutions on microbially induced carbonate precipitation and reinforcement of sand. Marine Georesources and Geotechnology, 2020, 38( 4): 450– 460

Kalantary F, Kahani M. Optimization of the biological soil improvement procedure. International Journal of Environmental Science and Technology, 2019, 16( 8): 4231– 4240

Martinez B, DeJong J, Ginn T, Montoya B, Barkouki T, Hunt C, Tanyu B, Major D. Experimental optimization of microbial-induced carbonate precipitation for soil improvement. Journal of Geotechnical and Geoenvironmental Engineering, 2013, 139( 4): 587– 598

Cui M J, Zheng J J, Zhang R J, Lai H J. Soil bio-cementation using an improved 2-step injection method. Arabian Journal of Geosciences, 2020, 13( 23): 1270–

Al Qabany A, Soga K, Santamarina C. Factors affecting efficiency of microbially induced calcite precipitation. Journal of Geotechnical and Geoenvironmental Engineering, 2012, 138( 8): 992– 1001

Feng K, Montoya B M. Drained shear strength of MICP sand at varying cementation levels. In: Proceedings of the International Foundations Congress and Equipment Expo 2015. San Antonio: American Society of Civil Engineers, 2015, 2242–2251

Gao Y, Hang L, He J, Chu J. Mechanical behaviour of biocemented sands at various treatment levels and relative densities. Acta Geotechnica, 2019, 14( 3): 697– 707

Montoya B M, DeJong J T, Boulanger R W. Dynamic response of liquefiable sand improved by microbial-induced calcite precipitation. Geotechnique, 2013, 63( 4): 302– 312

Montoya B, DeJong J. Stress-strain behavior of sands cemented by microbially induced calcite precipitation. Journal of Geotechnical and Geoenvironmental Engineering, 2015, 141( 6): 04015019–

Mujah D, Shahin M, Cheng L. Performance of biocemented sand under various environmental conditions. In: XVIII Brazilian Conference on Soil Mechanics and Geotechnical Engineering The Sustainable Future of Brazil goes through our Minas COBRAMSEG 2016. Belo Horizonte: Minas Gerais, 2016, 19–22

Jiang N J, Yoshioka H, Yamamoto K, Soga K. Ureolytic activities of a urease-producing bacterium and purified urease enzyme in the anoxic condition: Implication for subseafloor sand production control by microbially induced carbonate precipitation (MICP). Ecological Engineering, 2016, 90 : 96– 104

Mortensen B M, Haber M J, DeJong J T, Caslake L F, Nelson D C. Effects of environmental factors on microbial induced calcium carbonate precipitation. Journal of Applied Microbiology, 2011, 111( 2): 338– 349

Cardoso R, Pedreira R, Duarte S, Monteiro G, Borges H, Flores-Colen I. Biocementation as rehabilitation technique of porous materials. In: Delgado JMPQ (ed) New Approaches to Building Pathology and Durability. Singapore: Springer Singapore, 2016, 99–120

Hata T, Tsukamoto M, Inagaki Y, Mori H, Kuwano R, Gourc J P. Evaluation of multiple soil improvement techniques based on microbial functions. In: Proceedings of Geo-Frontiers 2011. Dallas: American Society of Civil Engineers, 2011, 3945–3955

Zhang C, Dehoff K, Hess N, Oostrom M, Wietsma T W, Valocchi A J, Fouke B W, Werth C J. Pore-scale study of transverse mixing induced CaCO ₃ precipitation and permeability reduction in a model subsurface sedimentary system. Environmental Science & Technology, 2010, 44( 20): 7833– 7838

Nemati M, Voordouw G. Modification of porous media permeability, using calcium carbonate produced enzymatically in situ. Enzyme and Microbial Technology, 2003, 33( 5): 635– 642

Yang Y, Chu J, Xiao Y, Liu H, Cheng L. Seepage control in sand using bioslurry. Construction & Building Materials, 2019, 212 : 342– 349

Feng K, Montoya B M. Quantifying level of microbial-induced cementation for cyclically loaded sand. Journal of Geotechnical and Geoenvironmental Engineering, 2017, 143( 6): 06017005–

Simatupang M, Okamura M. Liquefaction resistance of sand remediated with carbonate precipitation at different degrees of saturation during curing. Soil and Foundation, 2017, 57( 4): 619– 631

Darby K M, Hernandez G L, DeJong J T, Boulanger R W, Gomez M G, Wilson D W. Centrifuge model testing of liquefaction mitigation via microbially induced calcite precipitation. Journal of Geotechnical and Geoenvironmental Engineering, 2019, 145( 10): 04019084–

Mele L, Tian J T, Lirer S, Flora A, Koseki J. Liquefaction resistance of unsaturated sands: Experimental evidences and theoretical interpretation. Geotechnique, 2019, 69( 6): 541– 553

Montoya B M, DeJong J T, Boulanger R W, Wilson D W, Gerhard R, Ganchenko A, Chou J C. Liquefaction mitigation using microbial induced calcite precipitation. In: Proceedings of GeoCongress 2012. Oakland: American Society of Civil Engineers, 2012, 1918–1927

Zamani A, Montoya B M. Shearing and Hydraulic Behavior of MICP Treated Silty Sand. In: Geotechnical Frontiers 2017. Orlando: American Society of Civil Engineers, 290–299

Amaratunga A, Grozic J. On the undrained unloading behaviour of gassy sands. Canadian Geotechnical Journal, 2009, 46( 11): 1267– 1276

Fourie A B, Hofmann B A, Mikula R J, Lord E R F, Robertson P K. Partially saturated tailings sand below the phreatic surface. Geotechnique, 2001, 51( 7): 577– 585

Grozic J L, Robertson P, Morgenstern N. Cyclic liquefaction of loose gassy sand. Canadian Geotechnical Journal, 2000, 37( 4): 843– 856

He J, Chu J. Undrained responses of microbially desaturated sand under monotonic loading. Journal of Geotechnical and Geoenvironmental Engineering, 2014, 140( 5): 04014003–

Rebata-Landa V, Santamarina J C. Mechanical effects of biogenic nitrogen gas bubbles in soils. Journal of Geotechnical and Geoenvironmental Engineering, 2012, 138( 2): 128– 137

Wang L Y, van Paassen L A, Kavazanjian E Jr. Feasibility study on liquefaction mitigation of fraser river sediments by microbial induced desaturation and precipitation (MIDP). Geo-Congress, 2020, 2020 : 121– 131

Mirshekari M, Ghayoomi M. Centrifuge tests to assess seismic site response of partially saturated sand layers. Soil Dynamics and Earthquake Engineering, 2017, 94 : 254– 265

O’Donnell S T, Kavazanjian Jr E. The effect of desaturation on the static and cyclic mechanical response of dense sand. In: International Foundation Congress and Equipment Expo 2018. Orlando: American Society of Civil Engineers, 2018, 232–241

Okamura M, Soga Y. Effects of pore fluid compressibility on liquefaction resistance of partially saturated sand. Soil and Foundation, 2006, 46( 5): 695– 700

Wang L Y, van Paassen L A, Gao Y Q, He J, Gao Y F, Kim D. Laboratory tests on mitigation of soil liquefaction using microbial induced desaturation and precipitation. Geotechnical Testing Journal, 2021, 44( 2): 520– 534

Yang J, Savidis S, Roemer M. Evaluating liquefaction strength of partially saturated sand. Journal of Geotechnical and Geoenvironmental Engineering, 2004, 130( 9): 975– 979

Zhang B, Muraleetharan K K, Liu C. Liquefaction of Unsaturated Sands. International Journal of Geomechanics, 2016, 16( 6): D4015002–

He J, Chu J, Ivanov V. Remediation of liquefaction potential of sand using the biogas method. Geo-congress, 2013, 2013 : 879– 887

Wu S F. Mitigation of liquefaction hazards using the combined biodesaturation and bioclogging method. Dissertation for the Doctoral Degree. Iowa State University, Ames, 2015

Kavazanjian E Jr, O’Donnell S T. Mitigation of earthquake-induced liquefaction via microbial denitrification: A two-phase process. IFCEE 2015, 2286–2295

Nakano A. Microbe-induced desaturation of sand using pore pressure development via denitrification. Géotechnique Letters, 2018, 8( 1): 1– 4

Wang K, Chu J, Wu S, He J. Stress–strain behaviour of bio-desaturated sand under undrained monotonic and cyclic loading. Geotechnique, 2021, 71( 6): 521– 533

Hall C, Hernandez G, Darby K M, van Paassen L, Kavazanjian E, DeJong J, Wilson D. Centrifuge model testing of liquefaction mitigation via denitrification-induced desaturation. In: Proceedings of Geotechnical Earthquake Engineering and Soil Dynamics IV. Sacramento: American Society of Civil Engineers, 2018, 117–126

Pham V P, van Paassen L A, van der Star W R L, Heimovaara T J. Evaluating strategies to improve process efficiency of denitrification-based MICP. Journal of Geotechnical and Geoenvironmental Engineering, 2018, 144( 8): 04018049–

Filet A, Gadret J, Loygue M, Borel S. Biocalcis and its applications for the consolidation of sands. In: Proceedings of the Fourth International Conference on Grouting and Deep Mixing. New Orleans: American Society of Civil Engineers, 2012, 1767–1780

van Paassen L A, Harkes M P, van Zwieten G A, van der Zon W H, van der Star W R L, van Loosdrecht M C M. Scale up of BioGrout: A biological ground reinforcement method. In: Proceedings of the 17th international conference on soil mechanics and geotechnical engineering. Lansdale: IOS Press, 2009, 2328–2333

van Paassen L. Bio-mediated ground improvement: from laboratory experiment to pilot applications. In: Geo-Frontiers 2011: Advances in Geotechnical Engineering. Dallas: American Society of Civil Engineers, 2011, 4099–4108

Wu S F, Li B, Chu J. Large-scale model tests of biogrouting for sand and rock. Proceedings of the Institution of Civil Engineers—Ground Improvement, 2019, 1– 10

Johnston C, Trefry M, Rayner J, Ragusa S, De Zoysa D, Davis G. In situ bioclogging for the confinement and remediation of groundwater hydrocarbon plumes. In: Proceedings of the 1999 contaminated site remediation conference. Fremantle: Centre for Groundwater Studies, 1999

Ross N, Bickerton G. Application of biobarriers for groundwater containment at fractured bedrock sites. Remediation Journal, 2002, 12( 3): 5– 21

Castegnier F, Ross N, Chapuis R P, Deschênes L, Samson R. Long-term persistence of a nutrient-starved biofilm in a limestone fracture. Water Research, 2006, 40( 5): 925– 934

Blauw M, Lambert J, Latil M N. Biosealing: A method for in situ sealing of leakages. In: Proceedings of the International Symposium on Ground Improvement Technologies and Case Histories. Singapore: Research Publishing Services, 2009

Lambert J, Novakowski K, Blauw M, Latil M, Knight L, Bayona L. Pamper bacteria, they will help us: application of biochemical mechanisms in geo-environmental engineering. In: GeoFlorida 2010: Advances in Analysis, Modeling & Design. Florida: American Society of Civil Engineers, 2010, 618–627

Cuthbert M O, McMillan L A, Handley-Sidhu S, Riley M S, Tobler D J, Phoenix V R. A field and modeling study of fractured rock permeability reduction using microbially induced calcite precipitation. Environmental Science & Technology, 2013, 47( 23): 13637– 13643

Phillips A J, Cunningham A B, Gerlach R, Hiebert R, Hwang C, Lomans B P, Westrich J, Mantilla C, Kirksey J, Esposito R, Spangler L. Fracture sealing with microbially-induced calcium carbonate precipitation: A field study. Environmental Science & Technology, 2016, 50( 7): 4111– 4117

Phillips A J, Troyer E, Hiebert R, Kirkland C, Gerlach R, Cunningham A B, Spangler L, Kirksey J, Rowe W, Esposito R. Enhancing wellbore cement integrity with microbially induced calcite precipitation (MICP): A field scale demonstration. Journal of Petroleum Science Engineering, 2018, 171 : 1141– 1148

Gomez M G, Martinez B C, DeJong J T, Hunt C E, deVlaming L A, Major D W, Dworatzek S M. Field-scale bio-cementation tests to improve sands. Proceedings of the Institution of Civil Engineers-Ground Improvement, 2015, 168( 3): 206– 216

Gomez M G, Anderson C M, Graddy C M R, DeJong J T, Nelson D C, Ginn T R. Large-scale comparison of bioaugmentation and biostimulation approaches for biocementation of sands. Journal of Geotechnical and Geoenvironmental Engineering, 2017, 143( 5): 04016124–

Gomez M G, DeJong J T, Anderson C M. Effect of bio-cementation on geophysical and cone penetration measurements in sands. Canadian Geotechnical Journal, 2018, 55( 11): 1632– 1646

Gomez M G, Graddy C M R, DeJong J T, Nelson D C. Biogeochemical changes during bio-cementation mediated by stimulated and augmented ureolytic microorganisms. Scientific Reports, 2019, 9( 1): 11517–

Omoregie A I, Palombo E A, Ong D E L, Nissom P M. Biocementation of sand by Sporosarcina pasteurii strain and technical-grade cementation reagents through surface percolation treatment method. Construction & Building Materials, 2019, 228 : 116828–

Omoregie A I, Ngu L H, Ong D E L, Nissom P M. Low-cost cultivation of Sporosarcina pasteurii strain in food-grade yeast extract medium for microbially induced carbonate precipitation (MICP) application. Biocatalysis and Agricultural Biotechnology, 2019, 17 : 247– 255

Kahani M, Kalantary F, Soudi M R, Pakdel L, Aghaalizadeh S. Optimization of cost effective culture medium for Sporosarcina pasteurii as biocementing agent using response surface methodology: Up cycling dairy waste and seawater. Journal of Cleaner Production, 2020, 253 : 120022–

Dilrukshi R A N, Nakashima K, Kawasaki S. Soil improvement using plant-derived urease-induced calcium carbonate precipitation. Soil and Foundation, 2018, 58( 4): 894– 910

Hamdan N, Kavazanjian E Jr. Enzyme-induced carbonate mineral precipitation for fugitive dust control. Geotechnique, 2016, 66( 7): 546– 555

Kavazanjian E Jr, Almajed A, Hamdan N. Bio-inspired soil improvement using EICP soil columns and soil nails. In: Grouting 2017. Honolulu: American Society of Civil Engineers, 2017, 13–22

Nafisi A, Safavizadeh S, Montoya B M. Influence of microbe and enzyme-induced treatments on cemented sand shear response. Journal of Geotechnical and Geoenvironmental Engineering, 2019, 145( 9): 06019008–

Gao Y, He J, Tang X, Chu J. Calcium carbonate precipitation catalyzed by soybean urease as an improvement method for fine-grained soil. Soil and Foundation, 2019, 59( 5): 1631– 1637

Nam I H, Chon C M, Jung K Y, Choi S G, Choi H, Park S S. Calcite precipitation by ureolytic plant ( Canavalia ensiformis) extracts as effective biomaterials. KSCE Journal of Civil Engineering, 2015, 19( 6): 1620– 1625

Park S S, Choi S G, Nam I H. Effect of plant-induced calcite precipitation on the strength of sand. Journal of Materials in Civil Engineering, 2014, 26( 8): 06014017–

Dilrukshi R A N, Watanabe J, Kawasaki S. Strengthening of sand cemented with calcium phosphate compounds using plant-derived urease. International Journal of Geomate, 2016, 11( 25): 2461– 2467

Pham V P, Nakano A, van der Star W R L, Heimovaara T J, van Paassen L A. Applying MICP by denitrification in soils: a process analysis. Environmental Geotechnics, 2018, 5( 2): 79– 93