T K Sharma1, M Alazhari2, A Heath2, K Paine2, R M Cooper1. 1. Department of Biology and Biochemistry, University of Bath, Bath, UK. 2. BRE Centre for Innovative Construction Materials, University of Bath, Bath, UK.
Abstract
AIMS: Characterization of alkaliphilic Bacillus species for spore production and germination and calcite formation as a prelude to investigate their potential in microcrack remediation in concrete. METHODS AND RESULTS: Conditions, extent and timing of endospore production was determined by dark-field light microscopy; germination induction and kinetics were assessed by combining reduction in optical density with formation of refractile bodies by phase-contrast microscopy. Bacillus pseudofirmus was selected from several species as the most suitable isolate. Levels and timing of calcium carbonate precipitated in vitro by B. pseudofirmus were evaluated by atomic absorption spectroscopy and structural identity confirmed as calcite and aragonite by Raman spectroscopy and FTIR. The isolate produced copious spores that germinated rapidly in the presence of germinants l-alanine, inosine and NaCl. Bacterial cells produced CaCO3 crystals in microcracks and the resulting occlusion markedly restricted water ingress. CONCLUSIONS: By virtue of rapid spore production and germination, calcium carbonate formation in vitro and in situ, leading to sealing of microcracks, B. pseudofirmus shows clear potential for remediation of concrete on a commercial scale. SIGNIFICANCE AND IMPACT OF THE STUDY: Microbial sealing of microcracks should become a practicable and sustainable means of increasing concrete durability.
AIMS: Characterization of alkaliphilic Bacillus species for spore production and germination and calcite formation as a prelude to investigate their potential in microcrack remediation in concrete. METHODS AND RESULTS: Conditions, extent and timing of endospore production was determined by dark-field light microscopy; germination induction and kinetics were assessed by combining reduction in optical density with formation of refractile bodies by phase-contrast microscopy. Bacillus pseudofirmus was selected from several species as the most suitable isolate. Levels and timing of calcium carbonate precipitated in vitro by B. pseudofirmus were evaluated by atomic absorption spectroscopy and structural identity confirmed as calcite and aragonite by Raman spectroscopy and FTIR. The isolate produced copious spores that germinated rapidly in the presence of germinants l-alanine, inosine and NaCl. Bacterial cells produced CaCO3 crystals in microcracks and the resulting occlusion markedly restricted water ingress. CONCLUSIONS: By virtue of rapid spore production and germination, calcium carbonate formation in vitro and in situ, leading to sealing of microcracks, B. pseudofirmus shows clear potential for remediation of concrete on a commercial scale. SIGNIFICANCE AND IMPACT OF THE STUDY: Microbial sealing of microcracks should become a practicable and sustainable means of increasing concrete durability.
Authors: Sing Chuong Chuo; Sarajul Fikri Mohamed; Siti Hamidah Mohd Setapar; Akil Ahmad; Mohammad Jawaid; Waseem A Wani; Asim Ali Yaqoob; Mohamad Nasir Mohamad Ibrahim Journal: Materials (Basel) Date: 2020-11-05 Impact factor: 3.623