Salish Sea Response to Global Climate Change, Sea Level Rise, and Future Nutrient Loads

Khangaonkar, Tarang; Nugraha, Adi; Xu, Wenwei; Balaguru, Karthik

doi:10.1029/2018jc014670

Cited by 37 publications

(42 citation statements)

References 49 publications

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“…To analyze near-future changes in the larval phase, we used data from the Pacific Northwest National Laboratory's Salish Sea Model 50,71 , a hydrodynamic and water quality model of the Salish Sea, including a baseline condition in the year 2014, and a future projected oceanographic condition for the year 2095 modeled under an RCP 8.5 high CO 2 emissions scenario. Each model includes roughly 16,000 nodes throughout the larger Salish Sea region with values at 10 sigma layers between surface and bottom at each node.…”

Section: Methods Experimental Designmentioning

confidence: 99%

Temperature and salinity, not acidification, predict near-future larval growth and larval habitat suitability of Olympia oysters in the Salish Sea

Lawlor

Arellano

2020

Sci Rep

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Most invertebrates in the ocean begin their lives with planktonic larval phases that are critical for dispersal and distribution of these species. Larvae are particularly vulnerable to environmental change, so understanding interactive effects of environmental stressors on larval life is essential in predicting population persistence and vulnerability of species. Here, we use a novel experimental approach to rear larvae under interacting gradients of temperature, salinity, and ocean acidification, then model growth rate and duration of olympia oyster larvae and predict the suitability of habitats for larval survival. We find that temperature and salinity are closely linked to larval growth and larval habitat suitability, but larvae are tolerant to acidification at this scale. We discover that present conditions in the Salish Sea are actually suboptimal for olympia oyster larvae from populations in the region, and that larvae from these populations might actually benefit from some degree of global ocean change. Our models predict a vast decrease in mean pelagic larval duration by the year 2095, which has the potential to alter population dynamics for this species in future oceans. Additionally, we find that larval tolerance can explain large-scale biogeographic patterns for this species across its range. Many marine invertebrates begin their lives as tiny planktonic larvae that drift in the water column and disperse away from their parents. For sessile species, these larval periods are especially important as they are the only times throughout life history during which organisms are capable of dispersal. As such, survival during the larval phase is critical for the persistence of populations. Larvae are highly sensitive to environmental conditions 1,2 and the vast majority of larvae do not live to competence, so population demographics and geographic distributions of species are closely related to patterns of larval survival and metamorphosis along environmental gradients 3,4. Thus, responses of early life-history stages to the environmental conditions in the larval habitat help to explain and predict the structures of communities in coastal oceans. Understanding environmental influence on life-history bottlenecks is particularly important as climate variables that affect fitness are rapidly changing. Though the list of anthropogenically-influenced climate variables is broad and regionally variable, three of the most important environmental factors to consider are ocean temperature, acidification, and salinity. Broadly, temperature influences physiology of ectotherms, and thermal tolerances largely dictate distributions of marine organisms 5 ; changes in ocean temperature can cause changes in developmental rate and survival that delimit range boundaries of species 6,7. Acidification, or the shift of carbonate chemistry of a system, can affect calcification of animals with carbonate skeletons 8,9 and, thus, will disproportionately affect many essential ecosystem engineers in marine systems such as corals, bivalves,...

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Section: Methods Experimental Designmentioning

confidence: 99%

Temperature and salinity, not acidification, predict near-future larval growth and larval habitat suitability of Olympia oysters in the Salish Sea

Lawlor

Arellano

2020

Sci Rep

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“…This is particularly true for the hydrodynamic components of these 3D baroclinic tools that use turbulence closure schemes for parameterizing eddy viscosity and mixing processes. As a result, the models accurately reproduce tidal circulation, stratification, and exchange flows in the estuaries extending from the upstream river inflow boundary to the ocean boundary typically set at the continental shelf 54 . When applied in high resolution over the nearshore intertidal regions, the models employ wetting and drying techniques to represent flooding 97 and are able to represent tidal processes over tidal distributaries, tidal flats and marsh regions.…”

Section: Challenges For Constraining Coastal Dynamicsmentioning

confidence: 89%

“…For example, mangroves cover 0.1% of the Earth's surface 50 but are among the most productive carbon-sequestering ecosystems on Earth (1023 Mg C ha −1 ) and thus are hot spots for carbon storage and uptake from regional 51 to global scales 52 . More broadly, estuaries could be considered hot spots for productivity, carbon storage 53 , and/or decomposition 54 depending on hydrologic factors such as water residence time, estuarine exchange flow patterns, and position of the estuarine turbidity maximum zone 11 . For example,…”

Section: Challenges For Constraining Coastal Dynamicsmentioning

confidence: 99%

Representing the function and sensitivity of coastal interfaces in Earth system models

et al. 2020

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Between the land and ocean, diverse coastal ecosystems transform, store, and transport material. Across these interfaces, the dynamic exchange of energy and matter is driven by hydrological and hydrodynamic processes such as river and groundwater discharge, tides, waves, and storms. These dynamics regulate ecosystem functions and Earth's climate, yet global models lack representation of coastal processes and related feedbacks, impeding their predictions of coastal and global responses to change. Here, we assess existing coastal monitoring networks and regional models, existing challenges in these efforts, and recommend a path towards development of global models that more robustly reflect the coastal interface. T he coastal interface, where the land and ocean realms meet (e.g., estuaries, tidal wetlands, tidal rivers, continental shelves, and shorelines), is home to some of the most biologically and geochemically active and diverse systems on Earth 1. Although this interface only represents a small fraction of the Earth's surface, it supports a large suite of ecosystem services,

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“…Listed models were developed in whole or in part by EPA, except the Pacific Northwest National Laboratory's Salish Sea Model. Model references: VELMA (Abdelnour et al 2011(Abdelnour et al , 2013McKane et al 2014b); SMURF (Snyder et al 2019); CORESET (Melbourne-Thomas et al 2011a, b); HexSim (Schumaker et al 2014); EPA H2O (Russell et al 2015); HWBI (Orlando et al 2017); Salish Sea Model (Khangaonkar et al 2018(Khangaonkar et al , 2019; CMAQ (Luecken et al 2019); BenMAP-CE (Davidson et al 2007;Berman et al 2012) decision makers in balancing ecological, economic and social criteria over timescales relevant to immediate needs and long-term planning goals. A major challenge in modeling coastal ecosystems is the establishment of a coupled human-natural modeling framework capable of addressing transfers of terrestrial nutrients and toxic chemicals to marine waters, and consequent impacts on marine life and ecosystem goods and services.…”

Section: Potential Additional Envision Plug-ins For Coastal Ecosystemmentioning

confidence: 99%

“…• Existing Oregon State University ENVISION Puget Sound applications (Bolte and Vache 2010; http://envision.bioe.orst.edu/StudyAreas/PugetSound/). • Ongoing EPA Puget Sound applications of VELMA (McKane et al 2018a, b, c) • Pacific Northwest National Laboratory applications of the Salish Sea Model (SSM) (Khangaonkar et al 2018(Khangaonkar et al , 2019, coupled with National Oceanic and Atmospheric Administration applications of the Atlantis model (Levin et al 2009), for simulating the circulation and fate of terrestrial pollutant inputs within the Puget Sound marine ecosystem and consequent impacts on water quality, fisheries and threatened food web species. • Existing and new ENVISION plug-ins developed by EPA and others for extending ENVISION's applicability to coastal ecosystems (Tables 1 and 2).…”

Section: Potential Additional Envision Plug-ins For Coastal Ecosystemmentioning

confidence: 99%

An Integrated Multi-Model Decision Support Framework for Evaluating Ecosystem-Based Management Options for Coupled Human-Natural Systems

McKane

Brookes

Djang

et al. 2020

Ecosystem-Based Management, Ecosystem Services and Aquatic Biodiversity

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Simulation models offer a way to achieve a comprehensive understanding of the consequences of alternative community planning scenarios. For example, a community might want to understand how a particular decision-such as expanding an urban growth boundary into lands zoned for agriculture-will result in ecological, economic, and social tradeoffs for various stakeholder groups. This chapter explores the utility of ENVISION, a spatially-explicit decision support framework that integrates various ecological and human systems model "plug-ins" for informing Ecosystem-Based Management (EBM) options. While ENVISION already has a reasonably large tool box of such plug-ins, its usefulness could be further extended to address a wider range of community and ecosystem types. We specifically examine how a suite of existing U.S. Environmental Protection Agency decision support tools (VELMA, HexSim, CORESET, Coral PF and others) could significantly extend ENVISION's plug-in toolbox for coastal ecosystem EBM, inclusive of terrestrial-marine interactions and restoration goals of coastal communities dependent on marine ecosystem services.

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Salish Sea Response to Global Climate Change, Sea Level Rise, and Future Nutrient Loads

Cited by 37 publications

References 49 publications

Temperature and salinity, not acidification, predict near-future larval growth and larval habitat suitability of Olympia oysters in the Salish Sea

Temperature and salinity, not acidification, predict near-future larval growth and larval habitat suitability of Olympia oysters in the Salish Sea

Representing the function and sensitivity of coastal interfaces in Earth system models

An Integrated Multi-Model Decision Support Framework for Evaluating Ecosystem-Based Management Options for Coupled Human-Natural Systems

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