The World of Edges in Submerged Vegetated Marine Canopies: From Patch to Canopy Scale

Colomer, Jordi; Serra, Teresa

doi:10.3390/w13172430

Cited by 7 publications

(5 citation statements)

References 186 publications

(265 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, EO based monitoring of shallow waters and seabed of the coastal environment characterized by anthropogenic impacts, still represents a challenge, due to coastal water turbidity often associated with various atmospheric effects and noises, combined with the difficulties of in situ sampling for collecting sea truth calibration data of submerged plants on the seabed by means of scuba diving. These are important limiting factors to useful exploitation of EO high resolution (HR) data for extensive mapping of PO and coastal seabed and water quality parameters [14,19], especially where the coastal sea currents are significant, as in the Southern Mediterranean islands, with consequent additional signal degradations from increased water turbidity from sediment resuspension and sun-glint presence [20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Satellite Multi/Hyper Spectral HR Sensors for Mapping the Posidonia oceanica in South Mediterranean Islands

et al. 2021

View full text Add to dashboard Cite

The Mediterranean basin is a hot spot of climate change where the Posidonia oceanica (L.) Delile (PO) and other seagrasses are under stress due to its effect on marine coastal habitats and the rising influence of anthropogenic activities (i.e., tourism, fishery). The PO and seabed ecosystems, in the coastal environments of Pantelleria and Lampedusa, suffer additional growing impacts from tourism in synergy with specific stress factors due to increasing vessel traffic for supplying potable water and fossil fuels for electrical power generation. Earth Observation (EO) data, provided by high resolution (HR) multi/hyperspectral operative satellite sensors of the last generation (i.e., Sentinel 2 MSI and PRISMA) have been successfully tested, using innovative calibration and sea truth collecting methods, for monitoring and mapping of PO meadows under stress, in the coastal waters of these islands, located in the Sicily Channel, to better support the sustainable management of these vulnerable ecosystems. The area of interest in Pantelleria was where the first prototype of the Italian Inertial Sea Wave Energy Converter (ISWEC) for renewable energy production was installed in 2015, and sea truth campaigns on the PO meadows were conducted. The PO of Lampedusa coastal areas, impacted by ship traffic linked to the previous factors and tropicalization effects of Italy’s southernmost climate change transitional zone, was mapped through a multi/hyper spectral EO-based approach, using training/testing data provided by side scan sonar data, previously acquired. Some advanced machine learning algorithms (MLA) were successfully evaluated with different supervised regression/classification models to map seabed and PO meadow classes and related Leaf Area Index (LAI) distributions in the areas of interest, using multi/hyperspectral data atmospherically corrected via different advanced approaches.

show abstract

Section: Introductionmentioning

confidence: 99%

Satellite Multi/Hyper Spectral HR Sensors for Mapping the Posidonia oceanica in South Mediterranean Islands

et al. 2021

View full text Add to dashboard Cite

show abstract

“…As such, many seagrass species are intolerant to these conditions and are unable to grow in intertidal zones (Koch, 2001). However, there are some species, including a few temperate species such as Nanozostera japonica ( Zostera japonica ), Z. marina , Z. noltei ( Z. noltii ), as well as subtropical or tropical species such as Halophila ovalis and Thalassia hemprichii , that thrive in the shallow intertidal zones of estuaries, lagoons and other coastal areas (Colomer & Serra, 2021; Shafer et al., 2007). Intertidal seagrass meadows function as essential foraging habitats (Espadero et al., 2020) and blue carbon stock, yielding higher organic carbon burial rates than subtidal seagrasses (de los Santos et al., 2022).…”

Section: Introductionmentioning

confidence: 99%

Trade‐Off Between Light Deprivation and Desiccation in Intertidal Seagrasses Due To Periodic Tidal Inundation and Exposure: Insights From a Data‐Calibrated Model

Wang,

Adams,

Shao

2024

JGR Biogeosciences

View full text Add to dashboard Cite

Some seagrass species thrive in shallow intertidal zones globally, adapting to periodic tidal inundation and exposure with distinctive physiological traits and offering crucial ecosystem services. However, predicting the responses of intertidal seagrasses to external stressors is hampered by the complexity of the dynamic and harsh environments they occupy. Intertidal seagrass growth models, especially those incorporating dynamic physiological responses, are scarce in the literature. Our study comprehensively collated relevant data from the literature to parameterize the relationship between air exposure, seagrass leaf water content and photosynthetic efficiency to inform new growth rate functions for generalizable intertidal seagrass growth models. We tested the applicability of these model formulations for scenarios with varying physiological process assumptions, seagrass species, tidal conditions, meadow elevations and water turbidity. We found that neglecting air‐exposed physiological responses (i.e., leaf water content loss and reduced photosynthetic efficiency) can substantially overestimate seagrass growth rates. We also observed a trade‐off between light deprivation and desiccation on intertidal seagrass growth under specific tidal ranges and turbidity conditions. This can yield an “optimal” elevation where overall stress of desiccation (increasing with meadow elevation) and light deprivation (decreasing with meadow elevation) are minimized. The predicted optimal elevation, that is, the most suitable habitat for intertidal seagrass, moves upward as water turbidity increases. Our study provides conceptual and quantitative guidance for ecological modelers to include air exposure responses of intertidal seagrasses in coastal ecosystem models. The model also helps to evaluate the viability of intertidal seagrass habitats and inform decisions on coastal ecosystem management under changing environmental conditions.

show abstract

“…As such, many seagrass species are intolerant to these conditions and are unable to grow in intertidal zones (Koch 2001). However, there are some species, including a few temperate species in the genus Zostera such as Zostera japonica , Z. marina , Z. noltii , as well as subtropical or tropical species such as Halophila ovalis and Thalassia hemprichii , that thrive in the shallow intertidal zones of estuaries, lagoons and other coastal areas (Colomer and Serra 2021; Shafer et al 2007). Intertidal seagrass meadows function as essential foraging habitats (Espadero et al 2020) and blue carbon stock, yielding higher organic carbon burial rates than subtidal seagrasses (de los Santos et al 2022).…”

Section: Introductionmentioning

confidence: 99%

“…However, there are some species, including a few temperate species in the genus Zostera such as Zostera japonica, Z. marina, Z. noltii, as well as subtropical or tropical species such as Halophila ovalis and Thalassia hemprichii, that thrive in the shallow intertidal zones of estuaries, lagoons and other coastal areas (Colomer and Serra 2021;Shafer et al 2007).…”

Section: Introductionmentioning

confidence: 99%

Trade-off between light deprivation and desiccation in intertidal seagrasses due to periodic tidal inundation and exposure: insights from a data-calibrated model

Wang,

Adams,

Shao

2023

Preprint

View full text Add to dashboard Cite

Many seagrass species thrive in shallow intertidal zones globally, adapting to periodic tidal inundation and exposure with distinctive physiological traits and offering crucial ecosystem services. However, predicting the responses of intertidal seagrasses to external stressors is hampered by the complexity of the dynamic and harsh environments they occupy. Consequently, intertidal seagrass growth models, especially those incorporating dynamic physiological responses, are scarce in the literature. Our study comprehensively collated relevant data from the literature to parameterize the relationship between air exposure, seagrass leaf water content and photosynthetic efficiency to inform new growth rate functions for generalisable intertidal seagrass growth models. We tested the applicability of these model formulations for scenarios with varying physiological process assumptions, seagrass species, tidal conditions, meadow elevations and water turbidity. We found that neglecting air-exposed physiological responses (i.e., leaf water content loss and reduced photosynthetic efficiency) can substantially overestimate seagrass growth rates. We also observed a trade-off between light deprivation and desiccation on intertidal seagrass growth under specific tidal ranges and turbidity conditions. This can yield an “optimal” elevation where combined stressors of desiccation (increasing with meadow elevation) and light deprivation (decreasing with meadow elevation) are minimized. The predicted optimal elevation, i.e., the most suitable habitat for intertidal seagrass, moves upward as water turbidity increases. Our study provides both conceptual and quantitative guidance for ecological modellers to include air exposure responses of intertidal seagrasses in coastal ecosystem models. The model also helps to evaluate the viability of intertidal seagrass habitats and inform site selection for seagrass restoration.

show abstract

The World of Edges in Submerged Vegetated Marine Canopies: From Patch to Canopy Scale

Cited by 7 publications

References 186 publications

Satellite Multi/Hyper Spectral HR Sensors for Mapping the Posidonia oceanica in South Mediterranean Islands

Satellite Multi/Hyper Spectral HR Sensors for Mapping the Posidonia oceanica in South Mediterranean Islands

Trade‐Off Between Light Deprivation and Desiccation in Intertidal Seagrasses Due To Periodic Tidal Inundation and Exposure: Insights From a Data‐Calibrated Model

Trade-off between light deprivation and desiccation in intertidal seagrasses due to periodic tidal inundation and exposure: insights from a data-calibrated model

Contact Info

Product

Resources

About