Your search keyword '"Caitlin O. Blain"' showing total 4 results

1. Coastal darkening substantially limits the contribution of kelp to coastal carbon cycles

Author

Nick T. Shears, Sandra Christine Hansen, and Caitlin O. Blain

Subjects

Global and Planetary Change, Detritus, Ecology, biology, Kelp, chemistry.chemical_element, Forests, Carbon sequestration, biology.organism_classification, Kelp forest, Carbon Cycle, Carbon cycle, chemistry, Environmental chemistry, Dissolved organic carbon, Environmental Chemistry, Environmental science, Ecosystem, Biomass, Carbon, General Environmental Science

Abstract

Macroalgal-dominated habitats are rapidly gaining recognition as important contributors to marine carbon cycles and sequestration. Despite this recognition, relatively little is known about the production and fate of carbon originating from these highly productive ecosystems, or how anthropogenic- and climate-related stressors affect the role of macroalgae in marine carbon cycles. Here, we examine the impact of increasing turbidity on carbon storage, fixation and loss in southern hemisphere kelp forests. We quantified net primary production (NPP) and biomass accumulation (BA), and estimated carbon release via detritus and dissolved organic carbon (DOC) across a large-scale turbidity gradient. We show that increased turbidity, resulting in a 63% reduction in light, can result in a 95% reduction in kelp productivity. When averaged annually, estimates of NPP and BA per plant at high-light sites were nearly six and two times greater than those at low-light sites, respectively. Furthermore, the quantity of carbon fixed annually by kelp forests was up to 4.7 times greater than that stored as average annual standing stock. At low-light sites, the majority of C goes directly into tissue growth and is subsequently eroded. In contrast, excess production at high-light sites accounts for up to 39% of the total carbon fixed and is likely released as DOC. Turbidity is expected to increase in response to climate change and our results suggest this will have significant impacts on the capacity of kelp forests to contribute to carbon sequestration pathways. In addition to demonstrating that turbidity significantly reduces the quantity of carbon fixed by kelp forests, and subsequently released as detritus, our results highlight the negative impacts of turbidity on a large source of previously unaccounted for carbon.

Published

2021

2. Nutrient enrichment offsets the effects of low light on growth of the kelpEcklonia radiata

Author

Nick T. Shears and Caitlin O. Blain

Subjects

Nutrient, biology, Botany, Kelp, Environmental science, Aquatic Science, Ecklonia radiata, Oceanography, biology.organism_classification

Published

2020

3. Morphology and photosynthetic response of the kelpEcklonia radiataacross a turbidity gradient

Author

S. Christine Hansen, Caitlin O. Blain, T. Alwyn V. Rees, and Nick T. Shears

Subjects

Morphology (linguistics), biology, Botany, Kelp, Environmental science, Aquatic Science, Turbidity, Ecklonia radiata, Oceanography, Photosynthesis, biology.organism_classification

Published

2019

4. Seasonal and spatial variation in photosynthetic response of the kelp Ecklonia radiata across a turbidity gradient

Author

Caitlin O. Blain and Nick T. Shears

Subjects

0106 biological sciences, 0301 basic medicine, Radiata, Acclimatization, Kelp, Plant Science, Photosynthetic pigment, Photosynthetic efficiency, Ecklonia radiata, Photosynthesis, 01 natural sciences, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Photons, biology, Ecology, Ecklonia, Cell Biology, General Medicine, biology.organism_classification, Kelp forest, 030104 developmental biology, chemistry, Environmental science, Seasons, 010606 plant biology & botany

Abstract

Understanding the photoacclimation response of macroalgae across broad spatial and temporal scales is necessary for predicting their vulnerability to environmental changes and quantifying their contribution to coastal primary production. This study investigated how the photosynthesis–irradiance response and photosynthetic pigment content of the kelp Ecklonia radiata varies both spatially and seasonally among seven sites located across a turbidity gradient in the Hauraki Gulf, north-eastern New Zealand. Photosynthesis–irradiance curves were derived under laboratory conditions for whole adult E. radiata using photorespirometry chambers. Lab-derived photosynthesis–irradiance curves in summer were also compared with in situ measurements made on kelp at each of the seven study sites. Photosynthetic parameters and pigments showed clear seasonal patterns across all sites as demonstrated by higher photosynthetic pigment levels and photosynthetic efficiency occurring in autumn and winter, and higher maximum rates of photosynthesis and respiration occurring in summer. Lamina biomass was similar across sites, yet thalli exhibited a clear photokinetic response to increasing turbidity. At turbid sites photosynthetic pigment levels and photosynthetic efficiency was higher, and respiration and saturation and compensation irradiances lower, compared to high-light sites. The results presented here further our understanding of low-light acclimation strategies in kelp and highlight the degree of seasonality in photosynthetic parameters. Though E. radiata demonstrates a clear capacity to photoacclimate to a degrading light environment, further research is needed to investigate the extent to which the observed acclimation can offset the likely negative effects of increasing turbidity on kelp forest primary production.

Published

2018