Effects of mixing water salinity on the properties of concrete

Dhondy, Tanaz; Yu, Xiaojun; Yu, Tao; Teng, Jinguang

doi:10.1177/1369433220965272

Cited by 25 publications

(13 citation statements)

References 39 publications

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“…The salinity of pore solutions in concrete varies depending on the salt content of the water and the sand which are used in its production, which can be as high as ∼ 90 g/l when seawater and sea-sand are used [24]. Although growth was observed to be higher in MSM, which has a higher concentration of ions than the EZi medium (Figure 4), it is unclear how halotolerant strain MB284 is [25].…”

Section: Resultsmentioning

confidence: 99%

Evaluation of different strategies for efficient sporulation and germination of the MICP bacterium Lysinibacillus sphaericus strain MB284 (ATCC 13805)

Rahmaninezhad

Farnam

Schauer

et al. 2022

Preprint

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Environmental harsh conditions are one of the main challenges to the survivability of bacteria during the microbially induced calcium carbonate precipitation (MICP) process. Due to the high resistivity of endospores against inhospitable conditions in comparison with vegetative cells, different sporulation methods were applied to Lysinibacillus sphaericus strain MB284 by changing the environmental conditions to investigate the growth of germinated cells. It was found that the sporulation yield was more when both carbon source starvation and the thermal shock process were applied to this bacterium. In addition, extending the sporulation time of cells into the minimal medium at 2 °C for a couple of weeks had a great impact on improving the sporulation yield. Comparing the growth rate of germinated endospores in natural conditions (pH 7 and 25 °C) and harsh conditions (pH 12, temperature of -10 to 60 °C, salinity up to 100 g/l) showed that endospores generated by thermal shock are able to germinate in almost every inhospitable condition except at low pH (~3). Finally, exposing generated endospores before germination to harsh conditions (carbon source starving, high and low pH and temperature, and desiccation) for a nearly long period (to 100 days) showed that only low pH(~3) had a negative effect on the germination process and bacterial growth curve that indicated endospore of strain MB284 can be an appropriate solution for the problem of the survivability of bioagents in MICP. These results will provide helpful information about preparing and applying endospores of L. sphaericus for crack healing in concrete.

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Section: Resultsmentioning

confidence: 99%

Evaluation of different strategies for efficient sporulation and germination of the MICP bacterium Lysinibacillus sphaericus strain MB284 (ATCC 13805)

Rahmaninezhad

Farnam

Schauer

et al. 2022

Preprint

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“…Due to the presence of excessive sodium and calcium chloride in seawater sea sand concrete, the morphology of the pore structure densifies, which increased the number of micropores. This eventually increases the capillary tension and therefore generates substantially high drying shrinkage [60,61]. Additionally, the presence of seashell contents may have accounted for larger drying shrinkage in sea sand-based concrete, particularly due to the lower rigidity of sea-shell particles [62].…”

Section: Effect Of Sand Typementioning

confidence: 99%

Workability, strength, and shrinkage of ultra-high-performance seawater, sea sand concrete with different OPC replacement ratios

Saleh

Hamed

et al. 2022

Journal of Sustainable Cement-Based Materials

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An experimental investigation on the chemical, physical, mechanical, and shrinkage of seawater and sea sand-based ultra-high-performance concrete (UHP-SWSSC) with supplementary cementitious materials (SCM) (i.e., slag and silica fume) is reported. Several mixes were designed with varying proportions of SCMs (25%, 37.5%, 50%, and 62.5% of binder), aggregate source, and water-to-binder ratio. Heat evolution, density, workability, compressive strength development, and long-term autogenous and drying shrinkage of UHP-SWSSC were monitored. Seawater accelerates cement hydration as reflected in the heat evolution, and consequently, dictates the early-age strength, and autogenous shrinkage. SCM addition although limits the early-age strength development offers a comparable 90 days strength. The chloride content increases from marine resources and may limit the application to non-structural components. Nonetheless, a UHP-SWSSC mix with 50% OPC replaced by 37.5% slag and 12.5% silica fume is recommended in this study, which can achieve satisfactory workability, long-term strength, and shrinkage properties.

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“…Nonetheless, the chloride content in seawater would affect the performance of the concrete over time and lead to a decrease in workability, durability, long-term strength, and the worst situation is the collapse of the structural element (Xiao et al, 2017). A lower water-cement ratio was also used in seawater concrete because the salinity of the seawater was found to affect the overall performance of the concrete (Dhondy et al, 2021). In addition, the use of seawater would slightly reduce the slump and spread of cement paste generated in the concrete mixture compared to Da B et al, 2021;Li et al, 2021;Yue C et al, 2021;Dhondy et al, 2020;He X et al,2020;Yin et al, 2020;Parvizi et al, 2020;Chen G et al, 2020;Mansyur & Permana, 2020;Ma H et al, 2020;Gao et al, 2020;Soares et al, 2020;Adnan et al, 2020;Li, L. G., et al, 2019;;Montanari L. et al, 2019;Yu H et al, 2019;Gong W et al, 2019;Madona & Sivakumar, 2019;Jiang et al, 2019;Younis et al, 2019;Tan Y et al, 2018;Younis et al, 2018;Duan et al, 2015) Flexural strength 5 Gao et al, 2020;Parvizi et al, 2020;Jiang et al, 2019;Duan et al, 2015) Splitting tensile strength 4 (Ting M.Z.Y.…”

Section: Effect Of Seawater On Concrete Workability and Densitymentioning

confidence: 99%

“…13(Ting M. Z.Y. et al, 2021;Dhondy et al, 2021;Sun et al, 2021;Gao et al, 2020;Parvizi et al, 2020;Ting M. Z. Y et al, 2020;Chen G et al, 2020;Soares et al, 2020;Li, L. G., et al, 2019;Younis et al, 2018;Xiao et al, 2017;Duan et al, 2015) Fig.4 -…”

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A Systematic Literature Review on the Effect of Seawater as A Promising Material on the Physical and Mechanical Performance of Concrete

Waliyo¹,

Noor²

2021

IJSCET

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Concrete is made from freshwater, cement, and aggregate and the only material shared with mankind, flora, and fauna is freshwater. One of the most concerning problems the world has been facing over the last few decades is the rising demand for freshwater due to the increasing global population and depleting source of freshwater by 2050. In Malaysia, the population is expected to rise from 32 million people in 2020 to 40.50 million people in 2050, which would correspondingly increase the demand for domestic houses, industrial areas, and other building construction as well as increase the overall usage of freshwater. The utilisation of seawater has been applied in constructing buildings and infrastructures since the time of the Roman Empire and the structures still survive for more than 2000 years against chemical attacks and underwater wave force. Given that seawater is considered an alternative mixing agent in concrete production, research on seawater-based concrete has continued to gain interest from the scientific community and undergone swift development. Therefore, the aim of this study was to present a systematic literature review on the recent development of concrete with seawater as the mixing agent and its effect on the physical and mechanical performance of the concrete. A four-stage investigation criterion was conducted for the data collection from the Scopus database, which includes the search parameter, identification, screening, and writing. The screening of the literature retrieved 53 articles, which were then classified based on the physical and mechanical properties of the concrete. Based on the review, the use of seawater as a single mixing agent reduced the physical and mechanical performance of the concrete. However, the incorporation of seawater with special chemical admixture, mineral admixture, and reinforcement with certain treatment resulted in a higher performance of the concrete. Finally, the review highlighted the various potential studies that can be performed to investigate the utilisation of seawater in the construction industry while achieving a sustainable solution to preserve the environment.

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Effects of mixing water salinity on the properties of concrete

Cited by 25 publications

References 39 publications

Evaluation of different strategies for efficient sporulation and germination of the MICP bacterium Lysinibacillus sphaericus strain MB284 (ATCC 13805)

Evaluation of different strategies for efficient sporulation and germination of the MICP bacterium Lysinibacillus sphaericus strain MB284 (ATCC 13805)

Workability, strength, and shrinkage of ultra-high-performance seawater, sea sand concrete with different OPC replacement ratios

A Systematic Literature Review on the Effect of Seawater as A Promising Material on the Physical and Mechanical Performance of Concrete

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