TY - JOUR
T1 - Habitat Complexity Affects the Structure but Not the Diversity of Sessile Communities on Tropical Coastal Infrastructure
AU - Chee, Su Yin
AU - Yee, Jean Chai
AU - Cheah, Chee Ban
AU - Evans, Ally Jane
AU - Firth, Louise B.
AU - Hawkins, Stephen John
AU - Strain, Elisabeth Marijke Anne
N1 - Funding Information:
We thank the staff, students, volunteers, and industrial trainees at the Centre for Marine and Coastal Studies and School of Housing Building and Planning, for their contributions in field work and supporting SDG14-Life Below Water. Equipment and facilities required for this project are from the Centre for Marine and Coastal Studies. We also thank Reef Design Lab Pty Ltd for designing and producing the tiles used during the study.
Funding Information:
This study was supported financially by The Rufford Foundation (Project no.: 20933-2), E&O Berhad, E&O Property (Penang) Sdn. Bhd., Macro Dimension Concrete Sdn. Bhd., Universiti Sains Malaysia Research University grants (Grant no.: 304/PPANTAI/650876/E117 and 304/PPANTAI/650827/E118), the Royal Society International Exchanges Grant (IE150435), the British Ecological Society Small Grant (5546-6590), the Ian Potter Foundation, Harding Miller Foundation, and The New South Wales Government Office of Science and Research. AE was supported by the Ecostructure project, which is part-funded by the European Regional Development Fund (ERDF) through the Ireland Wales Cooperation Programme 2014–2022.
Publisher Copyright:
© Copyright © 2021 Chee, Yee, Cheah, Evans, Firth, Hawkins and Strain.
PY - 2021/10/4
Y1 - 2021/10/4
N2 - Increasing human population, urbanisation, and climate change have resulted in the proliferation of hard coastal infrastructure such as seawalls and breakwaters. There is increasing impetus to create multifunctional coastal defence structures with the primary function of protecting people and property in addition to providing habitat for marine organisms through eco-engineering - a nature-based solutions approach. In this study, the independent and synergistic effects of physical complexity and seeding with native oysters in promoting diversity and abundances of sessile organisms were assessed at two locations on Penang Island, Malaysia. Concrete tiles with varying physical and biological complexity (flat, 2.5 cm ridges and crevices, and 5 cm ridges and crevices that were seeded or unseeded with oysters) were deployed and monitored over 12 months. The survival of the seeded oysters was not correlated with physical complexity. The addition of physical and biological complexity interacted to promote distinct community assemblages, but did not consistently increase the richness, diversity, or abundances of sessile organisms through time. These results indicate that complexity, whether physical or biological, is only one of many influences on biodiversity on coastal infrastructure. Eco-engineering interventions that have been reported to be effective in other regions may not work as effectively in others due to the highly dynamic conditions in coastal environment. Thus, it is important that other factors such as the local species pools, environmental setting (e.g., wave action), biological factors (e.g., predators), and anthropogenic stressors (e.g., pollution) should also be considered when designing habitat enhancements. Such factors acting individually or synergistically could potentially affect the outcomes of any planned eco-engineering interventions.
AB - Increasing human population, urbanisation, and climate change have resulted in the proliferation of hard coastal infrastructure such as seawalls and breakwaters. There is increasing impetus to create multifunctional coastal defence structures with the primary function of protecting people and property in addition to providing habitat for marine organisms through eco-engineering - a nature-based solutions approach. In this study, the independent and synergistic effects of physical complexity and seeding with native oysters in promoting diversity and abundances of sessile organisms were assessed at two locations on Penang Island, Malaysia. Concrete tiles with varying physical and biological complexity (flat, 2.5 cm ridges and crevices, and 5 cm ridges and crevices that were seeded or unseeded with oysters) were deployed and monitored over 12 months. The survival of the seeded oysters was not correlated with physical complexity. The addition of physical and biological complexity interacted to promote distinct community assemblages, but did not consistently increase the richness, diversity, or abundances of sessile organisms through time. These results indicate that complexity, whether physical or biological, is only one of many influences on biodiversity on coastal infrastructure. Eco-engineering interventions that have been reported to be effective in other regions may not work as effectively in others due to the highly dynamic conditions in coastal environment. Thus, it is important that other factors such as the local species pools, environmental setting (e.g., wave action), biological factors (e.g., predators), and anthropogenic stressors (e.g., pollution) should also be considered when designing habitat enhancements. Such factors acting individually or synergistically could potentially affect the outcomes of any planned eco-engineering interventions.
KW - blue-green infrastructure
KW - complexity
KW - ecological engineering
KW - greening-of-grey infrastructure
KW - nature-based solutions
KW - transplant
UR - http://www.scopus.com/inward/record.url?scp=85117209196&partnerID=8YFLogxK
U2 - 10.3389/fevo.2021.673227
DO - 10.3389/fevo.2021.673227
M3 - Article
AN - SCOPUS:85117209196
SN - 2296-701X
VL - 9
JO - Frontiers in Ecology and Evolution
JF - Frontiers in Ecology and Evolution
M1 - 673227
ER -