Characterizing the vulnerability of intertidal organisms in Olympic National Park to ocean acidification

Jones, John Anthony; Passow, Uta; Fradkin, Steven C.

doi:10.1525/elementa.312

Cited by 4 publications

(3 citation statements)

References 94 publications

(134 reference statements)

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“…It confers high productivity to the region and its fisheries, but also high vulnerability to low pH and DO (Checkley & Barth, 2009). The incorporation of seasonality should, therefore, improve vulnerability assessments for species in seasonal seas (Jones et al., 2018; Spencer et al., 2019). The regional model used to project the ocean conditions continues to experience seasonality in the projected ocean conditions in the future (2100), but despite an increase in the projected winds in the CMIP5 projections, the future upwelling intensity does not change much due to compensation from increased stratification (Howard et al., 2020; Siedlecki et al., 2021).…”

Section: Discussionmentioning

confidence: 99%

Seasonality and Life History Complexity Determine Vulnerability of Dungeness Crab to Multiple Climate Stressors

Siedlecki

Matassa

et al. 2021

AGU Advances

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Scaling climate change impacts from individual responses to population‐level vulnerability is a pressing challenge for scientists and society. We assessed vulnerability of the most valuable fished species in the Northwest U.S.—Dungeness crab—to climate stressors using a novel combination of ocean, population, and larval transport models with stage‐specific consequences of ocean acidification, hypoxia, and warming. Integration across pelagic and benthic life stages revealed increased population‐level vulnerability to each stressor by 2100 under RCP 8.5. Under future conditions, chronic vulnerability to low pH emerged year‐round for all life stages, whereas vulnerability to low oxygen continued to be acute, developing seasonally and impacting adults, which are critical to population growth. Our results demonstrate how ontogenetic habitat shifts and seasonal ocean conditions interactively impact population‐level vulnerability. Because most valuable U.S. fisheries rely on species with complex life cycles in seasonal seas, chronic and acute perspectives are necessary to assess population‐level vulnerability to climate change.

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Section: Discussionmentioning

confidence: 99%

Seasonality and Life History Complexity Determine Vulnerability of Dungeness Crab to Multiple Climate Stressors

Siedlecki

Matassa

et al. 2021

AGU Advances

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“…The data product can also inform biological assessments. Many regional species have inferred or known sensitivity to ocean acidification parameters (pCO 2 , partial pressure of CO 2 ; pH; and ) (Busch and McElhany, 2016;Jones et al, 2018). The early part of this time series was used to delineate the range of physical and biogeochemical conditions encountered by species of ecological or economic importance in the region (Reum et al, 2014(Reum et al, , 2016.…”

Section: Extended and Potential Future Applicationsmentioning

confidence: 99%

A decade-long cruise time series (2008–2018) of physical and biogeochemical conditions in the southern Salish Sea, North America

Alin,

Newton,

Feely

et al. 2024

Earth Syst. Sci. Data

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Abstract. Coastal and estuarine waters of the northern California Current system and southern Salish Sea host an observational network capable of characterizing biogeochemical dynamics related to ocean acidification, hypoxia, and marine heatwaves. Here, we compiled data sets from a set of cruises conducted in estuarine waters of Puget Sound (southern Salish Sea) and its boundary waters (Strait of Juan de Fuca and Washington coast). This data product provides data from a decade of cruises with consistent formatting, extended data quality control, and multiple units for parameters such as oxygen with different end use needs and conventions. All cruises obtained high-quality temperature, salinity, inorganic carbon, nutrient, and oxygen observations to provide insight into the dynamic distribution of physical and biogeochemical conditions in this large urban estuary complex on the west coast of North America. At all sampling stations, conductivity–temperature–depth (CTD) casts included sensors for measuring temperature, conductivity, pressure, and oxygen concentrations. Laboratory analyses of discrete water samples collected at all stations throughout the water column in Niskin bottles provided measurements of dissolved inorganic carbon (DIC), dissolved oxygen, nutrient (nitrate, nitrite, ammonium, phosphate, and silicate), and total alkalinity (TA) content. This data product includes observations from 35 research cruises, including 715 oceanographic profiles, with >7490 sensor measurements of temperature, salinity, and oxygen; ≥6070 measurements of discrete oxygen and nutrient samples; and ≥4462 measurements of inorganic carbon variables (i.e., DIC and TA). The observations comprising this cruise compilation collectively characterize the spatial and temporal variability in a region with large dynamic ranges of the physical (temperature = 6.0–21.8 ∘C, salinity = 15.6–34.0) and biogeochemical (oxygen = 12–481 µmol kg−1, dissolved inorganic carbon = 1074–2362 µmol kg−1, total alkalinity = 1274–2296 µmol kg−1) parameters central to understanding ocean acidification and hypoxia in this productive estuary system with numerous interacting human impacts on its ecosystems. All observations conform to the climate-quality observing guidelines of the Global Ocean Acidification Observing Network, the US National Oceanic and Atmospheric Administration's Ocean Acidification Program, and ocean carbon community best practices. This ongoing cruise time series supports the estuarine and coastal monitoring and research objectives of the Washington Ocean Acidification Center and US National Oceanic and Atmospheric Administration (NOAA) Ocean and Atmospheric Research programs, and it provides diverse end users with the information needed to frame biological impacts research, validate numerical models, inform state and tribal water quality and fisheries management, and support decision-makers. All 2008–2018 cruise time-series measurements used in this publication are available at https://doi.org/10.25921/zgk5-ep63 (Alin et al., 2022).

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“…Research suggests that even small changes in ocean conditions can have large ramifications for fisheries and aquaculture productivity, marine and coastal habitats, cultural heritage, and human health and wellbeing (Mauger et al 2015). Within the California Current Ecosystem, models indicate that 11 of 34 functional groups have a consistent negative relationship with ocean acidification (OA) conditions (Busch and McElhany 2016) and of the 697 intertidal species found within the Olympic National Park on the Washington State coastline, 80% may be vulnerable, as estimated by exposure and sensitivity, to OA (Jones, Passow, and Fradkin 2018). Puget Sound, an estuarine fjord in Washington State, has known vulnerabilities to low pH (Feely et al 2010;Bianucci et al 2018;Evans et al 2019) which are expected to become more severe over time (Fassbender et al 2018;Khangaonkar et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Understanding and Advancing Natural Resource Management in the Context of Changing Ocean Conditions

2021

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Changing ocean conditions, such as ocean acidification, hypoxia, and ocean warming, are impacting marine ecosystems and posing a variety of immediate and future challenges for natural resource managers and affiliated industries. In order to successfully facilitate adaptation and mitigation responses to changing ocean conditions, research efforts and synthesis products should be developed in collaboration with resource managers and decision makers. Using interviews and surveys, we sought to advance collaborative science approaches by identifying the most pressing concerns, barriers, and research and monitoring needs of natural resource managers in Washington State, USA, where marine waters are particularly vulnerable to changing ocean conditions. Survey participants indicated that they are most concerned by ocean acidification, followed by water temperature and hypoxia. Our findings reveal a desire to prioritize laboratory and in situ studies to identify survival thresholds of ecologically or commercially important organisms, specifically zooplankton, fish, Dungeness crab, and conditions that promote harmful algal blooms. Scientific literature and in-person workshops and meetings were the preferred way for survey participants to learn about new science and affiliated results. Our findings highlight a need for continued and expanded monitoring and research efforts, the development of interpretive science products for resource managers, and enhanced communication between entities before information on changing ocean conditions can be effectively incorporated into resource management and policy decisions.

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Characterizing the vulnerability of intertidal organisms in Olympic National Park to ocean acidification

Cited by 4 publications

References 94 publications

Seasonality and Life History Complexity Determine Vulnerability of Dungeness Crab to Multiple Climate Stressors

Seasonality and Life History Complexity Determine Vulnerability of Dungeness Crab to Multiple Climate Stressors

A decade-long cruise time series (2008–2018) of physical and biogeochemical conditions in the southern Salish Sea, North America

Understanding and Advancing Natural Resource Management in the Context of Changing Ocean Conditions

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