Towards a low CO2 emission building material employing bacterial metabolism (2/2): Prospects for global warming potential reduction in the concrete industry

Myhr, Anders; Røyne, Frida; Brandtsegg, Andreas Saur; Bjerkseter, Catho; Throne‐Holst, Harald; Borch, Anita; Wentzel, Alexander; Røyne, Anja

doi:10.1371/journal.pone.0208643

Cited by 19 publications

(13 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Within the cement, and especially on its surface, Ca(OH) 2 under consumption of CO 2 is converted to CaCO 3 and H 2 O [19]. This reaction from soluble Ca(OH) 2 leaching out from the cement into the crack to solid CaCO 3 is accelerated by bacteria present in the cement, which supply metabolic Ca 2+ ions from their nutrients, such as calcium propionate Ca(C 3 H 5 CO 2 ) 2 .…”

Section: Introductionmentioning

confidence: 99%

Transformation of Construction Cement to a Self-Healing Hybrid Binder

Müller

Tolba

Wang

et al. 2019

IJMS

View full text Add to dashboard Cite

A new biomimetic strategy to im prove the self-healing properties of Portland cement is presented that is based on the application of the biogenic inorganic polymer polyphosphate (polyP), which is used as a cement admixture. The data show that synthetic linear polyp, with an average chain length of 40, as well as natural long-chain polyP isolated from soil bacteria, has the ability to support self-healing of this construction material. Furthermore, polyP, used as a water-soluble Na-salt, is subject to Na+/Ca2+ exchange by the Ca2+ from the cement, resulting in the formation of a water-rich coacervate when added to the cement surface, especially to the surface of bacteria-containing cement/concrete samples. The addition of polyP in low concentrations (<1% on weight basis for the solids) not only accelerated the hardening of cement/concrete but also the healing of microcracks present in the material. The results suggest that long-chain polyP is a promising additive that increases the self-healing capacity of cement by mimicking a bacteria-mediated natural mechanism.

show abstract

Section: Introductionmentioning

confidence: 99%

Transformation of Construction Cement to a Self-Healing Hybrid Binder

Müller

Tolba

Wang

et al. 2019

IJMS

View full text Add to dashboard Cite

show abstract

“…Several biological mechanisms have been explored to support carbon-sequestration in concrete. These have included microbial-and fungal-driven pathways to produce CaCO3 as bio-cementation routes for reduced GHG emissions [52][53][54]. There are a variety of methods to produce such bio-cements, and depending on feedstocks, it has been proposed that these cements could lead to a reduction in GHG emissions of more than 70% relative to Portland cement [53].…”

Section: Biological Sequestration Methodsmentioning

confidence: 99%

“…These have included microbial-and fungal-driven pathways to produce CaCO3 as bio-cementation routes for reduced GHG emissions [52][53][54]. There are a variety of methods to produce such bio-cements, and depending on feedstocks, it has been proposed that these cements could lead to a reduction in GHG emissions of more than 70% relative to Portland cement [53]. Distinct from a mineralization process, plant biomass has been proposed as an alternative to mineral aggregates, where photosynthesis during cultivation could contribute to carbon-fixing [55,56] and can lower the embodied energy of the concrete [57].…”

Section: Biological Sequestration Methodsmentioning

confidence: 99%

Opportunities and challenges for engineering construction materials as carbon sinks

et al. 2021

View full text Add to dashboard Cite

Population growth and urbanization over the coming decades are anticipated to drive unprecedented demand for infrastructure materials and energy resources. Unfortunately, factors such as the degree of resource consumption, the energy-intensive nature of production, and the chemical-reaction driven emissions make infrastructure materials production industries among the greatest contributors to anthropogenic CO2 emissions. Yet there is an often-overlooked potential environmental benefit to infrastructure materials: most remain in use for decades and their long service lives can facilitate extended storage of carbon. In this perspective, we present an overview of recent technological advancements that can support infrastructure materials acting as a global, distributed carbon sink and discuss areas for further research and development. We present mechanisms to quantify the extent to which the embodied carbon will be removed from the carbon cycle for a long enough period of time to provide carbon sequestration and climate benefit. We conclude that it is possible to unlock the vast potential to engineer a carbon sequestration system that simultaneously meets societal need for expanding infrastructure systems; however, complexities in how these systems are engineered must be systematically and quantitatively incorporated into materials design.

show abstract

“…The certainly has the potential to penetrate the commercial market because it can be used to produce construction materials using low temperature and renewable energy sources [102].…”

Section: Compressive Strength Testmentioning

confidence: 99%

Bioprecipitation of calcium carbonate mediated by ureolysis: A review

Omoregie

Palombo

Nissom

2020

Environmental Engineering Research

View full text Add to dashboard Cite

Ureolysis-driven microbially induced carbonate precipitation (MICP) is a naturally occurring process facilitated through microbial activities and biogeochemical reactions to produce calcium carbonate (CaCO 3) mineral. MICP serves as an alternative ground improvement binder method to conventional technologies which is sustainable, requires low energy for its treatment process, results in a minimal carbon footprint and could offer economic benefits. In the last two decades, MICP has drawn great interest from the scientific community because of its practicality to stabilize granular soils, repair concrete cracks and remediate heavy metals. To obtain successful MICP application, it is vital to understand the conditions that favor its process. This paper, therefore, provides an overview of literature on CaCO 3 precipitation mediated by ureolysis-driven MICP and its mechanism. The review includes a discussion on sources of urease enzyme from microorganisms used to induce CaCO 3 crystal formation required for implementation of MCIP for ground improvement. Moreover, the key factors that influence the outcome of MICP and bio-engineering testing methods typically used to evaluate MICP performance are also highlighted. Finally, this review also provides insight on the current drawbacks (i.e. ammonium production, scaleup bioprocess and treatment cost) affecting MICP technology and recommendations for future consideration.

show abstract

Towards a low CO2 emission building material employing bacterial metabolism (2/2): Prospects for global warming potential reduction in the concrete industry

Cited by 19 publications

References 38 publications

Transformation of Construction Cement to a Self-Healing Hybrid Binder

Transformation of Construction Cement to a Self-Healing Hybrid Binder

Opportunities and challenges for engineering construction materials as carbon sinks

Bioprecipitation of calcium carbonate mediated by ureolysis: A review

Contact Info

Product

Resources

About