87 citations as recorded by crossref.

1. A feasible scale-up production of Sporosarcina pasteurii using custom-built stirred tank reactor for in-situ soil biocementation A. Omoregie et al.
2. Multifunctional, Sustainable, and Biological Non-Ureolytic Self-Healing Systems for Cement-Based Materials M. Fahimizadeh et al.
3. Influence of On-Site Low-Ureolysis Bacteria and High-Ureolysis Bacteria on the Effectiveness of MICP Processes Q. Wu & Y. Wang
4. Microbially induced calcium carbonate precipitation: a widespread phenomenon in the biological world M. Seifan & A. Berenjian
5. Effect of curing method on unconfined compressive strength of silty sand treated with Bacillus Megaterium A. Eberemu et al.
6. Microbial contribution to early marine cementation M. Diaz et al.
7. Performance evaluation of bio-concrete: An analysis of biomineralization capabilities, microstructural and mechanical properties P. Nair et al.
8. Microbially Induced Calcium Carbonate Precipitation in Construction Materials S. Bhutange & M. Latkar
9. Synergic effect of bio-enhanced cement with nano biomass silica and polycarboxylate ether: Enhancing strength and microstructure for sustainable construction N. Nageswari et al.
10. Microbial ureolysis in the seawater-catalysed urine phosphorus recovery system: Kinetic study and reactor verification W. Tang et al.
11. Micro-continuum modelling of injection strategies for microbially induced carbonate precipitation J. Minto et al.
12. Enhancing stability of sandy, clayey, and silty soils through microbial biostabilization with Sporosarcina pasteurii D. Jumbo-Flores et al.
13. Liquefaction resistance of Fraser River sand improved by a microbially-induced cementation G. Riveros & A. Sadrekarimi
14. Calcium carbonate precipitation by cave bacteria isolated from Kashmir Cave, Khyber Pakhtunkhwa, Pakistan S. Jan et al.
15. Study of the effect of temperature on microbially induced carbonate precipitation X. Sun et al.
16. State of the Art Review of Emerging and Biogeotechnical Methods for Liquefaction Mitigation in Sands M. Sharma et al.
17. Simplified biogeochemical numerical model to predict pore fluid chemistry and calcite precipitation during biocementation of soil M. Sharma et al.
18. Can Microbially Induced Calcite Precipitation (MICP) through a Ureolytic Pathway Be Successfully Applied for Removing Heavy Metals from Wastewaters? Á. Torres-Aravena et al.
19. Towards a low CO2 emission building material employing bacterial metabolism (1/2): The bacterial system and prototype production A. Røyne et al.
20. From Earth to Mars: a perspective on exploiting biomineralization for Martian construction S. Khoshtinat et al.
21. Investigation on the solidification of lithium slag by microbially induced calcium carbonate precipitation under room and low temperature: Mechanical properties and immobilization of beryllium and thallium J. Li et al.
22. Improvement Schemes for Bacteria in MICP: A Review J. Zhu et al.
23. Comparison of Effects of Different Nutrients on Stimulating Indigenous Soil Bacteria for Biocementation M. Amini Kiasari et al.
24. Effects of biological admixtures on hydration and mechanical properties of Portland cement paste H. Kim et al.
25. Mechanism and Strength Characteristics of Microbially Induced Carbonate Precipitation and Lime Composite Cured Soft Clay B. Wang et al.
26. Indigenous microbial communities as catalysts for early marine cements: An in vitro study M. Diaz et al.
27. Probing the Abyss: Bacteria-based self-healing in cementitious construction materials – A Review T. Sharma et al.
28. Improving the strength of sandy soils via ureolytic CaCO3solidification bySporosarcina ureae J. Whitaker et al.
29. Mineralization of calcium carbonate by cave bacteria Y. Kim et al.
30. Bioremediation of cadmium in a sandy and a clay soil by microbially induced calcium carbonate precipitation after one week incubation N. Ghorbanzadeh et al.
31. Optimization of bacterial sporulation using economic nutrient for self-healing concrete Y. Ryu et al.
32. Potential role for microbial ureolysis in the rapid formation of carbonate tufa mounds F. Medina Ferrer et al.
33. Synergistic effect of composite bacteria on self-healing process of concrete crack M. Ahmad et al.
34. Critical Review of Solidification of Sandy Soil by Microbially Induced Carbonate Precipitation (MICP) L. Chen et al.
35. Microbial Growth and Calcium Carbonate Nucleation Properties in Mineral Admixtures Q. Jin et al.
36. Effect of nutrient types on the hydration of cementitious materials with co-cultured bacteria H. Son & H. Kim
37. Unlocking the potential of microbes: biocementation technology for mine tailings restoration — a comprehensive review M. Mahabub et al.
38. Trends and opportunities for greener and more efficient microbially induced calcite precipitation pathways: a strategic review K. Bhadiyadra et al.
39. Crack repairing performance by soybean urease induced calcium carbonate precipitation (SICP) combined with fibers and lightweight aggregates Y. Wang et al.
40. Characterization of ureolysis and microbially induced calcium carbonate precipitation under different incubation and reaction conditions H. Joo et al.
41. Sealing of sand using spraying and percolating biogrouts for the construction of model aquaculture pond in arid desert V. Stabnikov et al.
42. Relationship between Bacterial Contribution and Self-Healing Effect of Cement-Based Materials O. Šovljanski et al.
43. Mechanism and application of a coating-free microbial self-healing agent in cement-based composites M. Cheng et al.
44. Induced polarization as a monitoring tool for in-situ microbial induced carbonate precipitation (MICP) processes S. Saneiyan et al.
45. Dolerite Fines Used as a Calcium Source for Microbially Induced Calcite Precipitation Reduce the Environmental Carbon Cost in Sandy Soil C. Casas et al.
46. Bacteria-induced mineral precipitation: a mechanistic review T. Hoffmann et al.
47. Microbiological Processes in Improving the Behavior of Soils for Civil Engineering Applications: A Critical Appraisal A. Jha
48. Effect of microbially induced cementation on the instability and critical state behaviours of Fraser River sand G. Riveros & A. Sadrekarimi
49. Copper and zinc removal from anaerobic digestates via Sporosarcina pasteurii induced precipitation: Effect of volatile fatty acids on process performance A. Soto et al.
50. Diversity of Sporosarcina-like Bacterial Strains Obtained from Meter-Scale Augmented and Stimulated Biocementation Experiments C. Graddy et al.
51. Microbial induced calcium carbonate precipitation at elevated pH values (>11) using Sporosarcina pasteurii J. Henze & D. Randall
52. Self-generated microbial population or cultured microflora – an important criterion toward development of an effective and economically viable road map for organic soil management R. Bera et al.
53. Microbially induced carbonate precipitation (MICP) for soil strengthening: A comprehensive review T. Fu et al.
54. Synergistic crack sealing and water transport reduction in bioengineered concrete using a multi-strain bacterial consortium immobilized in LECA I. Ahmad et al.
55. Microbial Induced Carbonate Precipitation Using a Native Inland Bacterium for Beach Sand Stabilization in Nearshore Areas P. Nayanthara et al.
56. Biologic improvement of a sandy soil using single and mixed cultures: A comparison study M. Khaleghi & M. Rowshanzamir
57. Recent developments and future prospects of micro-organisms in enhancement of soil for geotechnical engineering applications: A review A. Shukla & A. Sharma
58. Urea Hydrolysis and Calcium Carbonate Precipitation in Gypsum‐Amended Broiler Litter C. Burt et al.
59. Controlling the Distribution of Microbially Precipitated Calcium Carbonate in Radial Flow Environments N. Zambare et al.
60. Non‐sterile corn steep liquor a novel, cost effective and powerful culture media for Sporosarcina pasteurii cultivation for sand improvement S. Babakhani et al.
61. Zinc bioremediation in soil by two isolated L-asparaginase and urease producing bacteria strains N. Ghorbanzadeh et al.
62. <b>Present Status of Ground Improvement Technologies Using Micr</b><b>obial Functions </b> S. KAWASAKI
63. Microbiologically Induced Calcite Precipitation biocementation, green alternative for roads – is this the breakthrough? A critical review C. Portugal et al.
64. Effects of spray-dried co-cultured bacteria on cement mortar I. Jang et al.
65. High level of calcium carbonate precipitation achieved by mixed culture containing ureolytic and nonureolytic bacterial strains P. Harnpicharnchai et al.
66. Bio-improvement of dune sand by bacterial medium cultures using Sporosarcina urea and Bacillus subtilis M. Khaleghi et al.
67. Isolation and Identification of Local Bactria Produced from Soil-Borne Urease N. Ali et al.
68. Hybrid bacteria mediated cemented sand: Microcharacterization, permeability, strength, shear wave velocity, stress-strain, and durability M. Sharma et al.
69. Long-term sustainability of microbial-induced CaCO3 precipitation in aqueous media D. Gat et al.
70. Reducing Compressibility of the Expansive Soil by Microbiological‐Induced Calcium Carbonate Precipitation X. Li et al.
71. Classification of additives and their influence mechanisms in improving the performance of biologically induced carbonate precipitation Z. Wang et al.
72. Improvement of Coral Sand With MICP Using Various Calcium Sources in Sea Water Environment J. Peng et al.
73. Experimental optimisation of various cultural conditions on urease activity for isolated Sporosarcina pasteurii strains and evaluation of their biocement potentials A. Omoregie et al.
74. Large-scale spatial characterization and liquefaction resistance of sand by hybrid bacteria induced biocementation M. Sharma et al.
75. Soil bio-cementation treatment strategies: state-of-the-art review A. Omoregie et al.
76. Graphene oxide on microbially induced calcium carbonate precipitation G. Tang et al.
77. Enhancing concrete crack healing: Revealing the synergistic impacts of multicomponent microbial repair systems H. Huang et al.
78. Microbial induced calcite precipitation on macrostructural properties of concrete: a review U. Wilson et al.
79. Comparison of microbially induced calcium carbonate precipitation eligibility using sporosarcina pasteurii and bacillus licheniformis on two different sands Y. Saricicek et al.
80. Simple and efficient strategy for α-MnO2/C by in-situ synthesis and its performance for degrading urea process wastewater Y. He et al.
81. Microbial–chemical synergy in the immobilization of cadmium in contaminated floodplain soils: A field-mesocosm assessment of Sporosarcina pasteurii and SiO₂ nanoparticles Z. Han et al.
82. Pore-scale investigation of precipitation evolution in MICP-treated soil for enhanced uniformity and cementation under reactant concentration limitation Y. Chu et al.
83. A review on the potential challenges in the application of biocementation in cement-based materials, possible solutions and way forward S. Bhutange et al.
84. Aerobic non-ureolytic bacteria-based self-healing cementitious composites: A comprehensive review I. Justo-Reinoso et al.
85. An Alternative Biotechnological Tool for Magnesite Enrichment: Lactic Acid Bacteria Isolated from Soil D. Efe et al.
86. New insights into the role of pH and aeration in the bacterial production of calcium carbonate (CaCO3) M. Seifan et al.
87. The role of bacterial community in the formation of a stalactite in coral limestone areas of Taiwan by 16S rRNA gene amplicon surveys J. Chen et al.