Concrete design and biotic colonization at the interface with the human user
Authors: Mahon, A.M., Maggs, C.A., Basheer, P.A.M. and Johnson, M.P.
Journal: Applied Phycology
Volume: 6
Issue: 1
Pages: 162-177
eISSN: 2638-8081
DOI: 10.1080/26388081.2025.2481887
Abstract:Concrete coastal structures, at the interface of land and sea, are increasing in response to population pressure and rising sea levels. Maximizing biodiversity on these artificial structures is being approached using various eco-engineering methods, as an opportunity for bioreceptivity, but less attention has been given to how their biotic colonization will affect human users. Biotic composition and succession have an impact on the human use of the structures, as algae have varying levels of slipperiness, hence danger for users, and also influence degradation of concrete. The ecological engineering study reported in this article determined variation in biotic colonization among different concrete designs. Experimental blocks were deployed for 1 year in the intertidal zone to test differences in colonization among (i) a range of concrete mixes: manufactured with ordinary Portland cement (OPC); rapid hardening Portland cement (RHPC); OPC with microsilica (MS); and OPC with ground granulated blast furnace slag (GGBS) and (ii) different surface texture: surface obtained with controlled permeability formwork (CPF); trowel finished surface; surface obtained with wooden formwork; and patterned finish. Differences in algal colonization among different concrete mixes persisted for 9 of 12 months, with microsilica concrete having consistently higher algal coverage than other types of concretes. Surface finishes had a greater effect: in particular on CPF blocks, low algal growth and high grazer activity left the surface clear after 1 year of deployment, whereas trowel, formwork and patterned finishes had increasingly rapid colonization. Understanding the significance of concrete engineering techniques for ecological processes of an increasingly man-made coastline interfaces engineering with biology and applies to coastal ecosystems worldwide. Our study has shown through the integration of ecology and concrete engineering technology that techniques such as using CPF can greatly influence the resulting assemblages and hence affect attributes such as slipperiness (for users) and the speed of concrete erosion.
Source: Scopus