Design catalogue for eco-engineering of coastal artificial structures: a multifunctional approach for stakeholders and end-users

O'Shaughnessy, Kathryn A.; Hawkins, Stephen J.; Evans, Ally J.; Hanley, Mick E.; Lunt, Paul; Thompson, Richard C.; Francis, Robert A.; Hoggart, Simon; Moore, Pippa J.; Iglesias, G.; Simmonds, David; Ducker, James H.; Firth, Louise B.

doi:10.1007/s11252-019-00924-z

Cited by 84 publications

(47 citation statements)

References 115 publications

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“…Our results support previous suggestions that the addition of complexity to the homogenous, flat surfaces of coastal defence structures has the potential to improve ecological outcomes (O'Shaughnessy et al, 2020). As compared to the natural habitats they replace, topographically simple artificial structures commonly support reduced native biodiversity (Airoldi et al, 2015).…”

Section: Discussionsupporting

confidence: 88%

“…There has been increasing interest in how complexity might be incorporated into the design of marine urban structures so as to enhance their ecological value (O'Shaughnessy et al, 2020). The addition of complexity to topographically homogenous marine urban structures has been proposed as a mechanism by which the overall richness and abundances of key functional groups might be enhanced (Strain, Olabarria, et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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A global analysis of complexity–biodiversity relationships on marine artificial structures

Strain

Steinberg

Vozzo

et al. 2020

Global Ecol. Biogeogr.

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Aim Topographic complexity is widely accepted as a key driver of biodiversity, but at the patch‐scale, complexity–biodiversity relationships may vary spatially and temporally according to the environmental stressors complexity mitigates, and the species richness and identity of potential colonists. Using a manipulative experiment, we assessed spatial variation in patch‐scale effects of complexity on intertidal biodiversity. Location 27 sites within 14 estuaries/bays distributed globally. Time period 2015–2017. Major taxa studied Functional groups of algae, sessile and mobile invertebrates. Methods Concrete tiles of differing complexity (flat; 2.5‐cm or 5‐cm complex) were affixed at low–high intertidal elevation on coastal defence structures, and the richness and abundance of the colonizing taxa were quantified after 12 months. Results The patch‐scale effects of complexity varied spatially and among functional groups. Complexity had neutral to positive effects on total, invertebrate and algal taxa richness, and invertebrate abundances. However, effects on the abundance of algae ranged from positive to negative, depending on location and functional group. The tidal elevation at which tiles were placed accounted for some variation. The total and invertebrate richness were greater at low or mid than at high intertidal elevations. Latitude was also an important source of spatial variation, with the effects of complexity on total richness and mobile mollusc abundance greatest at lower latitudes, whilst the cover of sessile invertebrates and sessile molluscs responded most strongly to complexity at higher latitudes. Conclusions After 12 months, patch‐scale relationships between biodiversity and habitat complexity were not universally positive. Instead, the relationship varied among functional groups and according to local abiotic and biotic conditions. This result challenges the assumption that effects of complexity on biodiversity are universally positive. The variable effect of complexity has ramifications for community and applied ecology, including eco‐engineering and restoration that seek to bolster biodiversity through the addition of complexity.

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Section: Discussionsupporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

A global analysis of complexity–biodiversity relationships on marine artificial structures

Strain

Steinberg

Vozzo

et al. 2020

Global Ecol. Biogeogr.

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“…In an effort to promote more sustainable marine built environments, IGGI is being used to improve multifunctionality; in particular the ecological value of hard infrastructure. The field has flourished recently (Strain et al., 2018), with many successful examples emerging (see O'Shaughnessy et al, 2020 for review). It remains a comparatively young science, however, and has not been subject to the long‐term experimentation, implementation and critical evaluation that are necessary before being considered a mainstream solution.…”

Section: Greening Of the Grey: Making Space For Nature In The Marine mentioning

confidence: 99%

“…The emerging field of IGGI in the marine environment is producing numerous examples of multifunctional structures yielding multiple biodiversity benefits. This has been achieved through myriad techniques, including manipulating building materials composition, building in topographic complexity and transplanting organisms directly onto substrata (see O'Shaughnessy et al, 2020 for review). To date, much of this has been done by the research community on experimental scales and has typically been applied retrospectively to existing artificial structures.…”

Section: Arguments For/against Iggimentioning

confidence: 99%

Greening of grey infrastructure should not be used as a Trojan horse to facilitate coastal development

Firth

Airoldi

Bulleri

et al. 2020

Journal of Applied Ecology

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Climate change and coastal urbanization are driving the replacement of natural habitats with artificial structures and reclaimed land globally. These novel habitats are often poor surrogates for natural habitats. The application of integrated greening of grey infrastructure (IGGI) to artificial shorelines demonstrates how multifunctional structures can provide biodiversity benefits whilst simultaneously serving their primary engineering function. IGGI is being embraced globally, despite many knowledge gaps and limitations. It is a management tool to compensate anthropogenic impacts as part of the Mitigation Hierarchy. There is considerable scope for misuse and ‘greenwashing’ however, by making new developments appear more acceptable, thus facilitating the regulatory process. We encourage researchers to exercise caution when reporting on small‐scale experimental trials. We advocate that greater attention is paid to when experiments ‘fail’ or yield unintended outcomes. We advise revisiting, repeating and expanding on experiments to test responses over broader spatio‐temporal scales to improve the evidence base. Synthesis and applications. Where societal and economic demand makes development inevitable, particular attention should be paid to avoiding, minimizing and rehabilitating environmental impacts. Integrated greening of grey infrastructure (IGGI) should be implemented as partial compensation for environmental damage. Mutual benefits for both humans and nature can be achieved when IGGI is implemented retrospectively in previously developed or degraded environments. We caution, however, that any promise of net biodiversity gain from new developments should be scrutinized and any local ecological benefits set in the context of the wider environmental impacts. A ‘greened’ development will always impinge on natural systems, a reality that is much less recognized in the sea than on land.

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“…Worldwide experimental trials have tested the efficacy of different types of crevices (Coombes et al ., 2015), complexity of tiles (Loke et al ., 2014, 2015), boulder size and mix in gabions (Firth et al ., 2014) and retro-fitted artificial rockpools (Browne & Chapman, 2014; Evans et al ., 2016). Guidelines on practice are emerging (Morris et al ., 2019; O'Shaughnessy et al ., 2020) and this approach is now entering the planning (Evans et al ., 2016; Evans et al ., 2019) and engineering mainstream (Burcharth et al ., 2007). Additionally along the way some interesting insights have emerged on rock pool ecology (Firth et al ., 2013), topographic complexity and diversity (Loke et al ., 2016; Loke & Todd, 2016), mobile predators using the intertidal zone (Morris et al ., 2017), connectivity of matter and propagules (Bishop et al ., 2017; Heery et al ., 2017) plus difficult-to-study boulder shores (Chapman, 2017).…”

Section: Overview and Synthesismentioning

confidence: 99%

Rocky shores as tractable test systems for experimental ecology

et al. 2020

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Rocky shore ecology has been studied for a long time, starting with qualitative descriptions and becoming more quantitative and experimental over time. Some of the earliest manipulative experimental ecological studies were undertaken on rocky shores. Many, over time, have made considerable contributions to ecological theory, especially highlighting the importance of biological interactions at the community level. The suitability of rocky shores as convenient test systems for ecological experimentation is outlined. Here we consider contributions from rocky shores to the emerging concepts of supply-side ecology, the roles of competition, predation and grazing, disturbance and succession and positive interactions in structuring communities along environmental gradients. We then address alternative stable states, relationships between biodiversity and ecosystem functioning, and bottom-up and top-down control of ecosystems. We briefly consider the feedback and synergies between ecological concepts and experimental work on rocky shores, whilst still emphasizing the traditional values of marine natural history upheld in JMBA since its first publication. The importance of rigorous experimental designs championed by Underwood and co-workers is emphasized. Recent progress taking advantage of new technologies and emerging approaches is considered. We illustrate how experimental studies have shown the importance of biological interactions in modulating species and assemblage-level responses to climate change and informed conservation and management of coastal ecosystems.

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Design catalogue for eco-engineering of coastal artificial structures: a multifunctional approach for stakeholders and end-users

Cited by 84 publications

References 115 publications

A global analysis of complexity–biodiversity relationships on marine artificial structures

A global analysis of complexity–biodiversity relationships on marine artificial structures

Greening of grey infrastructure should not be used as a Trojan horse to facilitate coastal development

Rocky shores as tractable test systems for experimental ecology

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