Climate change overtakes coastal engineering as the dominant driver of hydrological change in a large shallow lagoon

Huang, Peisheng; Hennig, Karl; Kala, Jatin; Andrys, Julia

doi:10.5194/hess-24-5673-2020

Cited by 10 publications

(9 citation statements)

References 73 publications

(104 reference statements)

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“…Climate-related changes in the Baltic Sea like warmer temperatures, changed stratification patterns, altered ecosystems and biogeochemical pathways may change the fate of nutrients in the sea (Arheimer et al, 2012;Meier et al, 2012). Sea level rise may have an impact on the internal loading of phosphate, through potentially increased saltwater inflows in the future with rising sea levels, affecting ecosystems in micro-tidal lagoons (Huang et al, 2020) and increasing the hypoxic areas in the deep water and the associated phosphate release (Meier et al, 2017).…”

Section: Impacts Of Climate Change On Other Factorsmentioning

confidence: 99%

Human impacts and their interactions in the Baltic Sea region

et al. 2022

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Abstract. Coastal environments, in particular heavily populated semi-enclosed marginal seas and coasts like the Baltic Sea region, are strongly affected by human activities. A multitude of human impacts, including climate change, affect the different compartments of the environment, and these effects interact with each other. As part of the Baltic Earth Assessment Reports (BEAR), we present an inventory and discussion of different human-induced factors and processes affecting the environment of the Baltic Sea region, and their interrelations. Some are naturally occurring and modified by human activities (i.e. climate change, coastal processes, hypoxia, acidification, submarine groundwater discharges, marine ecosystems, non-indigenous species, land use and land cover), some are completely human-induced (i.e. agriculture, aquaculture, fisheries, river regulations, offshore wind farms, shipping, chemical contamination, dumped warfare agents, marine litter and microplastics, tourism, and coastal management), and they are all interrelated to different degrees. We present a general description and analysis of the state of knowledge on these interrelations. Our main insight is that climate change has an overarching, integrating impact on all of the other factors and can be interpreted as a background effect, which has different implications for the other factors. Impacts on the environment and the human sphere can be roughly allocated to anthropogenic drivers such as food production, energy production, transport, industry and economy. The findings from this inventory of available information and analysis of the different factors and their interactions in the Baltic Sea region can largely be transferred to other comparable marginal and coastal seas in the world.

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Section: Impacts Of Climate Change On Other Factorsmentioning

confidence: 99%

Human impacts and their interactions in the Baltic Sea region

et al. 2022

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“…These habitats often provide unique ecological services and are particularly important as nursery areas for estuarine-resident and freshwater fish species. Unfortunately, the productivity and resiliency of many estuaries and lagoons have been reduced by intensive habitat alteration and management (Heady et al 2015), and these habitats may be especially vulnerable to climate change (Huang et al 2020). In coastal California, there is growing evidence that extreme climatic events are becoming increasingly commonplace, altering the annual timing and duration of lagoon formation (i.e., sandbar open/close dynamics) and diminishing the quality of lagoon rearing habitat for imperiled juvenile salmonids (Osterback et al 2018;Huber and Carlson 2020).…”

Section: Discussionmentioning

confidence: 99%

Spatiotemporal Variability in Environmental Conditions Influences the Performance and Behavior of Juvenile Steelhead in a Coastal California Lagoon

Bond

Kiernan

Osterback

et al. 2021

Estuaries and Coasts

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In California (USA), seasonal lagoons provide important oversummer rearing habitat for juvenile steelhead trout (anadromous Oncorhynchus mykiss). However, key water quality parameters such as temperature and dissolved oxygen concentration can periodically approach or exceed the physiological tolerances of steelhead during the protracted dry season. A field study employing distributed temperature sensing technology, water quality monitoring, habitat mapping, and mark-recapture sampling was conducted to examine how shifting environmental conditions affected the performance and behavior of juvenile steelhead in the Scott Creek estuary/lagoon (Santa Cruz County). Abiotic conditions were driven by episodic inputs of seawater to the typically freshwater lagoon. During midsummer, the water column was vertically stratified which reduced suitable lagoon rearing habitat by approximately 40%. Nevertheless, steelhead abundance, growth, and condition factor were high during the summer and decreased in autumn following lagoon destratification and cooling. Unlike previous work, this study identified limited emigration from the lagoon to riverine habitat during the summer. Instead, juvenile steelhead exhibited crepuscular movement patterns within the lagoon, with peaks in upstream (to upper lagoon habitat) and downstream (to lower lagoon habitat) movement occurring at dawn and dusk, respectively. This study underscores that habitat complexity and connectivity are critical for juvenile steelhead production and persistence and provides insight into steelhead habitat use and behavior in seasonal lagoons.

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“…The residence time of water in an estuary (inversely related to the flushing rate, #1 Figure 1) is strongly influenced by freshwater flow (Wolanski et al, 2006;Huang et al, 2020). It affects the distribution of salinity, dissolved oxygen and resident organisms, sedimentation rates of particulates, processing times of nutrients, contaminants (e.g., toxins, heavy metals) and pathogens, and contaminant exposure risk to resident organisms (Cottingham et al, 2018;Clark and O'Connor, 2019;Fonseca et al, 2020).…”

Section: Hydrodynamicsmentioning

confidence: 99%

“…However, at the catchment scale, variability in the direction of changes has been observed between flow indices (Douglas et al, 2000) and the same flow indicator at different parts of the catchment (Fleming et al, 2020). Recent declines in freshwater flows have been observed in southern Australia (Zhang et al, 2016;Huang et al, 2020), the Mediterranean (Haddeland et al, 2014;Greve et al, 2018), southern Africa (Haddeland et al, 2014) and southern Asia (Mondal and Mujumdar, 2012). Conversely, increases have been observed for rivers flowing to the Arctic Ocean (Durocher et al, 2019), northern Europe (Haddeland et al, 2014;Greve et al, 2018) northern Asia (Tananaev et al, 2016) and northern North America (Durocher et al, 2019).…”

Section: Changes In Flow To Estuariesmentioning

confidence: 99%

Environmental Flow Requirements of Estuaries: Providing Resilience to Current and Future Climate and Direct Anthropogenic Changes

Chilton

Hamilton

Nagelkerken

et al. 2021

Front. Environ. Sci.

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Estuaries host unique biodiversity and deliver a range of ecosystem services at the interface between catchment and the ocean. They are also among the most degraded ecosystems on Earth. Freshwater flow regimes drive ecological processes contributing to their biodiversity and economic value, but have been modified extensively in many systems by upstream water use. Knowledge of freshwater flow requirements for estuaries (environmental flows or E-flows) lags behind that of rivers and their floodplains. Generalising estuarine E-flows is further complicated by responses that appear to be specific to each system. Here we critically review the E-flow requirements of estuaries to 1) identify the key ecosystem processes (hydrodynamics, salinity regulation, sediment dynamics, nutrient cycling and trophic transfer, and connectivity) modulated by freshwater flow regimes, 2) identify key drivers (rainfall, runoff, temperature, sea level rise and direct anthropogenic) that generate changes to the magnitude, quality and timing of flows, and 3) propose mitigation strategies (e.g., modification of dam operations and habitat restoration) to buffer against the risks of altered freshwater flows and build resilience to direct and indirect anthropogenic disturbances. These strategies support re-establishment of the natural characteristics of freshwater flow regimes which are foundational to healthy estuarine ecosystems.

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Climate change overtakes coastal engineering as the dominant driver of hydrological change in a large shallow lagoon

Cited by 10 publications

References 73 publications

Human impacts and their interactions in the Baltic Sea region

Human impacts and their interactions in the Baltic Sea region

Spatiotemporal Variability in Environmental Conditions Influences the Performance and Behavior of Juvenile Steelhead in a Coastal California Lagoon

Environmental Flow Requirements of Estuaries: Providing Resilience to Current and Future Climate and Direct Anthropogenic Changes

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