Abstract
Marine ecosystem monitoring requires observations of its attributes at different spatial and temporal scales that traditional sampling methods (e.g., RGB imaging, sediment cores) struggle to efficiently provide. Proximal optical sensing methods can fill this observational gap by providing observations of, and tracking changes in, the functional features of marine ecosystems non-invasively. Underwater hyperspectral imaging (UHI) employed in proximity to the seafloor has shown a further potential to monitor pigmentation in benthic and sympagic phototrophic organisms at small spatial scales (mm–cm) and for the identification of minerals and taxa through their finely resolved spectral signatures. Despite the increasing number of studies applying UHI, a review of its applications, capabilities, and challenges for seafloor ecosystem research is overdue. In this review, we first detail how the limited band availability inherent to standard underwater cameras has led to a data analysis “bottleneck” in seafloor ecosystem research, in part due to the widespread implementation of underwater imaging platforms (e.g., remotely operated vehicles, time-lapse stations, towed cameras) that can acquire large image datasets. We discuss how hyperspectral technology brings unique opportunities to address the known limitations of RGB cameras for surveying marine environments. The review concludes by comparing how different studies harness the capacities of hyperspectral imaging, the types of methods required to validate observations, and the current challenges for accurate and replicable UHI research.
Highlights
Applications of hyperspectral imaging for marine environments and organisms are still in the early stages of development; here, we report the findings of all studies in our knowledge as they all have something to add to this new field
[67] explain how their results were restricted by the lack of altitude corrections and attenuation of light in water, as spectral signatures of benthic organisms in deeper Underwater hyperspectral imaging (UHI) transects were different due to more blue wavelengths reaching the sensor compared to the signal from red bands
Our review of proximal UHI applications has showcased its potential for providing ecosystem attributes over a wide range of environments, allowing us to fill a niche gap in the spatial scales relevant for improved monitoring of impacts to marine ecosystems
Summary
The rapid and extensive effects of anthropogenic activities on marine seafloor ecosystems range in scales from global to local to individual organisms [1,2,3]. The state of marine ecosystems is accelerating towards a similar tipping point in biodiversity and ecosystem functioning first observed in terrestrial ecosystems before the Industrial Revolution [4,5]. Ecosystem-based management requires cost-efficient monitoring methods that guarantee accurate observations about the state and functioning of seafloor ecosystems and that are capable of synthesizing information at multiple spatial and ecological scales [9,10,11].
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