Influence of concrete properties on the initial biological colonisation of marine artificial structures
Natanzi, A.S.; Thompson, B.J.; Brooks, P.R.; Crowe, T.P.; McNally, C. (2021). Influence of concrete properties on the initial biological colonisation of marine artificial structures. Ecol. Eng. 159: 106104. https://dx.doi.org/10.1016/j.ecoleng.2020.106104
In: Ecological Engineering. Elsevier: Amsterdam; London; New York; Tokyo. ISSN 0925-8574; e-ISSN 1872-6992, more
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Artificial Marine Structures; Concrete Design; Ecological Engineering; Biodiversity Enhancement; Biofilm; Early colonisation |
| Authors | | Top |
- Natanzi, A.S.
- Thompson, B.J.
- Brooks, P.R.
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- Crowe, T.P., more
- McNally, C.
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| Abstract |
Artificial marine infrastructures now cover large stretches of the available natural shoreline in many parts of the world. This is having a substantial impact on the local marine ecosystems as biodiverse natural hard substrata are being replaced with man-made structures, which have been shown to support lower levels of biodiversity.The ecological value of artificial coastal structures could be enhanced through careful design of pre-fabricated ecologically engineered units. Material selection is a critical parameter in the design of these units. To maximise the potential of concrete units to support and increase biodiversity, this paper explores the impact of binder composition, aggregate type and plasticizer on surface chemistry and early biofilm formation which influence subsequent colonisation. Experiments in the current study have shown that the addition of ground granulated blast-furnace slag (GGBS) to the mix can increase the levels of biodiversity supported while maintaining engineering performance requirements in terms of strength, chloride resistance and alkalinity. Conversely the aggregate type and use of a plasticizer have a minor influence. In particular, the addition of GGBS was shown to increase the biomass of diatoms, cyanobacteria and green algae and barnacle abundance one month after immersion on both sheltered surfaces and those exposed to wave action. Results suggest that concrete composition can alter the surface chemistry of artificial structures and thereby can improve the ecological value of these structures as habitats for marine life. |
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