Coconut shell biochar–Bacillus cereus DKBovi-5 based biocomposite as a sustainable additive for cement mortar: Effect of pyrolysis temperature on characterization, strength, hydration, and healing
| dc.contributor.author | Anoop, P.P. | |
| dc.contributor.author | Palanisamy, T. | |
| dc.date.accessioned | 2026-02-03T13:19:35Z | |
| dc.date.issued | 2025 | |
| dc.description.abstract | Although biochar–bacteria composites have been explored for self-healing in cementitious materials, the influence of pyrolysis temperature on microbial compatibility and healing performance has been insufficiently investigated. This study addresses this gap by examining how pyrolysis temperature affects the physicochemical properties of coconut shell biochar and its effectiveness as a microbial carrier in mortar. Biochar produced at 300 °C, 400 °C, and 500 °C was characterized, and Bacillus cereus DKBovi-5 was immobilized onto it to form biocomposites. The biocomposites were incorporated into mortar to evaluate mechanical, microstructural, and crack healing performances. Characterization of biochar showed enhanced crystallinity at 500 °C as indicated by XRD, development of primary and secondary pores confirmed by FESEM, and increased micronutrient concentrations due to thermal enrichment observed through ICP-MS. Compressive strength restoration increased from 80.21 % to 91.23 % between 300 °C and 500 °C temperatures. TGA analysis, interpreted using Bhatty's method, indicated an increase in the degree of hydration from 61.65 % to 65.33 %. Rietveld refinement of XRD data revealed a rise in calcite content from 24 % to 51 %. FESEM imaging confirmed the deposition of hydration products within the biochar pores. Healing evaluation showed closure of cracks up to 0.762 mm and 0.920 mm in mortars with 300 °C and 500 °C biocomposites, respectively, corresponding to healed areas of 92.49 % and 100 %. The healed products in all biocomposites were confirmed as calcite through FESEM-EDS and XRD analyses. Optimized pyrolysis at 500 °C yielded a biocomposite with superior microbial healing performance, establishing its suitability as a self-healing admixture in bio-mortar applications. © 2025 Elsevier B.V. | |
| dc.identifier.citation | Sustainable Chemistry and Pharmacy, 2025, 46, , pp. - | |
| dc.identifier.uri | https://doi.org/10.1016/j.scp.2025.102112 | |
| dc.identifier.uri | https://idr.nitk.ac.in/handle/123456789/20156 | |
| dc.publisher | Elsevier B.V. | |
| dc.subject | anion | |
| dc.subject | bentonite | |
| dc.subject | calcium | |
| dc.subject | calcium carbonate | |
| dc.subject | calcium hydroxide | |
| dc.subject | cation | |
| dc.subject | cell enzyme | |
| dc.subject | cement | |
| dc.subject | charcoal | |
| dc.subject | copper | |
| dc.subject | drinking water | |
| dc.subject | inorganic compound | |
| dc.subject | iron | |
| dc.subject | magnesium | |
| dc.subject | manganese | |
| dc.subject | organic compound | |
| dc.subject | phosphorus | |
| dc.subject | potassium | |
| dc.subject | rain | |
| dc.subject | sodium | |
| dc.subject | trace element | |
| dc.subject | urease | |
| dc.subject | volatile organic compound | |
| dc.subject | water | |
| dc.subject | zinc | |
| dc.subject | adsorption | |
| dc.subject | Article | |
| dc.subject | Bacillus cereus | |
| dc.subject | Bacillus subtilis | |
| dc.subject | bacterial endospore | |
| dc.subject | bacterial metabolism | |
| dc.subject | bacterial spore | |
| dc.subject | bacterial strain | |
| dc.subject | bacterium carrier | |
| dc.subject | carbon sequestration | |
| dc.subject | chemical composition | |
| dc.subject | chemical interaction | |
| dc.subject | coconut | |
| dc.subject | compressive strength | |
| dc.subject | controlled study | |
| dc.subject | energy dispersive X ray spectroscopy | |
| dc.subject | environmental impact | |
| dc.subject | environmental temperature | |
| dc.subject | enzymatic hydrolysis | |
| dc.subject | enzyme activity | |
| dc.subject | field emission scanning electron microscopy | |
| dc.subject | Fourier transform infrared spectroscopy | |
| dc.subject | healing | |
| dc.subject | hydration | |
| dc.subject | immobilization | |
| dc.subject | inductively coupled plasma mass spectrometry | |
| dc.subject | ion chromatography | |
| dc.subject | isotherm | |
| dc.subject | microbial activity | |
| dc.subject | microbial adhesion | |
| dc.subject | microbial viability | |
| dc.subject | moisture | |
| dc.subject | molecular weight | |
| dc.subject | morphological trait | |
| dc.subject | morphology | |
| dc.subject | nonhuman | |
| dc.subject | nutrient solution | |
| dc.subject | particle size | |
| dc.subject | pH | |
| dc.subject | physical chemistry | |
| dc.subject | pore volume | |
| dc.subject | precipitation | |
| dc.subject | protein synthesis | |
| dc.subject | pyrolysis | |
| dc.subject | rainy season | |
| dc.subject | scanning electron microscopy | |
| dc.subject | sporogenesis | |
| dc.subject | temperature | |
| dc.subject | thermogravimetry | |
| dc.subject | volatilization | |
| dc.subject | water absorption | |
| dc.subject | water quality | |
| dc.subject | X ray diffraction | |
| dc.subject | zeta potential | |
| dc.title | Coconut shell biochar–Bacillus cereus DKBovi-5 based biocomposite as a sustainable additive for cement mortar: Effect of pyrolysis temperature on characterization, strength, hydration, and healing |