Studies
An individual study is a summary of a specific scientific study, providing background context, the conservation action(s) taken and their consequences.
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Study | Published | Actions | |
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Partial replacement of cement for waste aggregates in concrete coastal and marine infrastructure: a foundation for ecological enhancement? Based on: McManus R.S., Archibald N., Comber S., Knights A.M., Thompson R.C. & Firth L.B. (2018). Study Link |
2018 | 1 | |
Coral recruitment and early benthic community development on several materials used in the construction of artificial reefs and breakwaters Based on: Burt J., Bartholomew A., Bauman A., Saif A. & Sale P.F. (2009). Study Link |
2009 | 1 | |
Floating pontoons create novel habitats for subtidal epibiota Based on: Connell S.D. (2000). Study Link |
2000 | 1 | |
Influence of concrete properties on the initial biological colonisation of marine artificial structures Based on: Natanzi A.S., Thompson B.J., Brooks P.R., Crowe T.P. & McNally C. (2021). Study Link |
2021 | 1 | |
Little evidence that lowering the pH of concrete supports greater biodiversity on tropical and temperate seawalls Based on: Hsiung A.R., Tan W.T., Loke L.H.L., Firth L.B., Heery E.C., Ducker J., Clark V., Pek Y.S., Birch W.R., Ang A.C.F., Hartanto R.S., Chai T.M.F. & Todd P.A. (2020). Study Link |
2020 | 2 | |
Reefcrete: reducing the environmental footprint of concretes for eco-engineering marine structures Based on: Dennis H.D., Evans A.J., Banner A.J. & Moore P.J. (2018). Study Link |
2018 | 1 | |
Ecological consequences of the type of rock used in the construction of artificial boulder-fields Based on: Green D.S., Chapman M.G. & Blockley D.J. (2012). Study Link |
2012 | 1 | |
Colonization and weathering of engineering materials by marine microorganisms: an SEM study Based on: Coombes M.A., Naylor L.A., Thompson R.C., Roast S.D., Gómez‐Pujol L. & Fairhurst R.J. (2011). Study Link |
2011 | 1 | |
Availability of microhabitats explains a widespread pattern and informs theory on ecological engineering of boulder reefs Based on: Liversage K., Cole V., Coleman R. & McQuaid C. (2017). Study Link |
2017 | 1 | |
Engineering novel habitats on urban infrastructure to increase intertidal biodiversity Based on: Chapman M.G. & Blockley D.J. (2009). Study Link |
2009 | 2 | |
Between a rock and a hard place: environmental and engineering considerations when designing coastal defence structures Based on: Firth L.B., Thompson R.C., Bohn K., Abbiati M., Airoldi L., Bouma T.J., Bozzeda F., Ceccherelli V.U., Colangelo M.A., Evans A.J., Ferrario F., Hanley M.E., Hinz H., Hoggart S.P.G., Jackson J.E., Moore P., Morgan E.H., Perkol-Finkel S., Skov M.W., Strain E.M., van Belzen J. & Hawkins S.J. (2014). Study Link |
2014 | 10 | |
The role of geometric structure and texture on concrete for algal and macrofaunal colonization in the marine and estuarine intertidal zone Based on: Paalvast P. (2015) 77-84. Study Link |
2015 | 7 | |
Getting into the groove: opportunities to enhance the ecological value of hard coastal infrastructure using fine-scale surface textures Based on: Coombes M.A., La Marca E.C., Naylor L.A. & Thompson R.C. (2015). Study Link |
2015 | 1 | |
Seawall as salmon habitat: eco-engineering improves the distribution and foraging of juvenile Pacific salmon Based on: Sawyer A.C., Toft J.D. & Cordell J.R. (2020). Study Link |
2020 | 2 | |
Benches, beaches, and bumps: how habitat monitoring and experimental science can inform urban seawall design Based on: Cordell J.R., Toft J.D., Munsch S. & Goff M. (2017) CRC Press, 421-438. Study Link |
2017 | 2 | |
Interacting effects of habitat structure and seeding with oysters on the intertidal biodiversity of seawalls Based on: Strain E.M.A., Cumbo V.R., Morris R.L., Steinberg P.D. & Bishop M.J. (2020). Study Link |
2020 | 4 | |
Provision of refugia and seeding with native bivalves can enhance biodiversity on vertical seawalls Based on: Bradford T.E., Astudillo J.C., Lau E.T.C., Perkins M.J., Lo C.C., Li T.C.H., Lam C.S., Ng T.P.T., Strain E.M.A., Steinberg P.D. & Leung K.M.Y. (2020). Study Link |
2020 | 4 | |
Ecological enhancement of coastal engineering structures: passive enhancement techniques Based on: MacArthur M., Naylor L.A., Hansom J.D. & Burrows M.T. (2020). Study Link |
2020 | 2 | |
Eco-engineering rock pools to a seawall in a tropical estuary: microhabitat features and fine sediment accumulation Based on: Waltham N.J. & Sheaves M. (2018). Study Link |
2018 | 2 | |
Structural complexity and component type increase intertidal biodiversity independently of area Based on: Loke L.H.L. & Todd P.A. (2016). Study Link |
2016 | 8 | |
Habitat development along a highly urbanised foreshore Based on: Heath T. & Moody G. (2013) 1-7. Study Link |
2013 | 2 | |
Evaluation of ecological engineering of “armoured” shorelines to improve their value as habitat Based on: Chapman M.G. & Underwood A.J. (2011). Study Link |
2011 | 6 | |
Can coir increase native biodiversity and reduce colonisation of non-indigenous species in eco-engineered rock pools? Based on: Morris R.L., Golding S., Dafforn K.A. & Coleman R.A. (2018). Study Link |
2018 | 2 | |
Impact of recreational harvesting on assemblages in artificial rocky habitats Based on: Airoldi L., Bacchiocchi F., Cagliola C., Bulleri F. & Abbiati M. (2005). Study Link |
2005 | 2 | |
Artificial reefs as juvenile fish habitat in a marina Based on: Patranella A., Kilfoyle K., Pioch S. & Spieler R.E. (2017). Study Link |
2017 | 1 |
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