Climate-Mediated Changes to Linked Terrestrial and Marine Ecosystems across the Northeast Pacific Coastal Temperate Rainforest Margin

Bidlack, Allison; Bisbing, Sarah M.; Buma, Brian; Diefenderfer, Heida L.; Fellman, Jason B.; Floyd, William C.; Giesbrecht, Ian; Lally, Amritpal; Lertzman, Ken; Perakis, Steven S.; Butman, David; D’Amore, D. V.; Fleming, Sean W.; Hood, Eran; Hunt, Brian P. V.; Kiffney, Peter M.; McNicol, Gavin; Menounos, Brian; Tank, Suzanne E.

doi:10.1093/biosci/biaa171

Cited by 28 publications

(30 citation statements)

References 108 publications

(144 reference statements)

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“…In the near term, ongoing observations will be used to further elucidate land‐sea linkages and landscape controls on hydrological and ecological processes, in the context of regional gradients (Figure 1; Bidlack et al, 2021) and collaboration networks (Bidlack et al, 2017; Sullivan et al, 2017). Over the longer term, the KWO aims to support a broad range of local‐level and network‐level studies that capitalize on the unique opportunities of this observatory to study the changing coastal margin ecosystem.…”

Section: Emerging Results and Future Directionsmentioning

confidence: 99%

“…These factors result in highly dynamic and spatially variable catchment processes, which are challenging to measure and led us to use technologies for automated measurements. In this region, climate change is expected to increase the mean annual temperature, the mean annual precipitation (Wang et al, 2016) and the frequency of extreme precipitation events associated with atmospheric rivers (Radic et al, 2015; Sharma & Déry, 2019), among other changes with downstream implications (e.g., Bidlack et al, 2021; Shanley et al, 2015). Consequently, the KWO was designed to provide long‐term year‐round observations of weather, watershed hydrology and biogeochemistry and nearshore coastal ocean processes, in a poorly studied yet socially and economically important region.…”

Section: Introductionmentioning

confidence: 99%

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The Kwakshua Watersheds Observatory, central coast of British Columbia, Canada

Giesbrecht

Floyd

Tank

et al. 2021

Hydrological Processes

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The Kwakshua Watersheds Observatory (KWO) is an integrative watersheds observatory on the coastal margin of a rain‐dominated bog‐forest landscape in British Columbia (BC), Canada. Established in 2013, the goal of the KWO is to understand and model the flux of terrestrial materials from land to sea – the origins, pathways, processes and ecosystem consequences – in the context of long‐term environmental change. The KWO consists of seven gauged watersheds and a network of observation sites spanning from land to sea and along drainage gradients within catchments. Time‐series datasets include year‐round measurements of weather, soil hydrology, streamflow, aquatic biogeochemistry, microbial ecology and nearshore oceanographic conditions. Sensor measurements are recorded every 5 min and water samples are collected approximately monthly. Additional observations are made during high‐flow conditions. We used remote sensing to map watershed terrain, drainage networks, soils and terrestrial ecosystems. The watersheds range in size from 3.2 to 12.8 km2, with varying catchment characteristics that influence hydrological and biogeochemical responses. Despite local variation, the overall study area is a global hotspot for yields of dissolved organic carbon, dissolved organic nitrogen and dissolved iron at the coastal margin. This observatory helps fill an important gap in the global network of observatories, in terms of spatial location (central coast of BC), climate (temperate oceanic), hydrology (very high runoff, pluvial regime), geology (igneous intrusive, glacially scoured), vegetation (bog rainforest) and soils (large stores of organic carbon).

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Section: Emerging Results and Future Directionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Kwakshua Watersheds Observatory, central coast of British Columbia, Canada

Giesbrecht

Floyd

Tank

et al. 2021

Hydrological Processes

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“…Glacial and glacier supported regimes (Figure 7) are limited to high mountain watersheds in Southeast AK and BC (Figure 3), while a topographically controlled mix of pluvial and rain‐snow hybrid regimes dominate the rest of the SCR watersheds of Southeast AK (Curran & Biles, 2021; Edwards et al., 2013; O’Neel et al., 2015; Sergeant et al., 2020), BC (Bidlack et al., 2021; Eaton & Moore, 2010; Trubilowicz et al., 2013; Wade et al., 2001), and WA from Puget Sound northward (Fleming et al., 2007; Reidy Liermann et al., 2012; Sanborn & Bledsoe, 2006). Pluvial‐dominated hydrographs are nearly ubiquitous among SCRs south of Puget Sound WA (Bidlack et al., 2021; Lane et al., 2018; Reidy Liermann et al., 2012; Sanborn & Bledsoe, 2006), with a distinct “dry season” in CA (McManamay et al., 2014; Roden, 1967). By contrast, the comparatively “pure” nival regimes (Figure 7) are limited to the few large continental rivers that penetrate the coastal mountains from colder climates; for example, Skeena R. (Morrison et al., 2012) and Fraser R. (Fleming et al., 2007; Figure 3).…”

Section: Discussionmentioning

confidence: 99%

“…We used two separate approaches to place all watersheds into discrete types. First, we set aside 10 large continental watersheds (Figure S1 in Supporting Information S1) because we expected them to be fundamentally different from the SCR watersheds (e.g., Bidlack et al., 2021) in terms of catchment controls on river hydro‐biogeochemistry (e.g., watershed size, transit times, groundwater storage, agricultural land use, and fluvial network structure are likely of increasing importance). Second, we grouped the remaining 2,695 SCR watersheds into statistically similar clusters using k ‐means partitioning (Hastie et al., 2009) with 12 variables and 12 clusters, after exploring several permutations of different statistical clustering methods ( k ‐means, k ‐medoids, unsupervised random forest), different lists of input variables, and different numbers ( k ) of clusters (Figure 1).…”

Section: Methodsmentioning

confidence: 99%

Watershed Classification Predicts Streamflow Regime and Organic Carbon Dynamics in the Northeast Pacific Coastal Temperate Rainforest

Giesbrecht

Tank

Frazer³

et al. 2022

Global Biogeochemical Cycles

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Watershed classification has long been a key tool in the hydrological sciences, but few studies have been extended to biogeochemistry. We developed a combined hydro‐biogeochemical classification for watersheds draining to the coastal margin of the Northeast Pacific coastal temperate rainforest (1,443,062 km2), including 2,695 small coastal rivers (SCR) and 10 large continental watersheds. We used cluster analysis to group SCR watersheds into 12 types, based on watershed properties. The most important variables for distinguishing SCR watershed types were evapotranspiration, slope, snowfall, and total precipitation. We used both streamflow and dissolved organic carbon (DOC) measurements from rivers (n = 104 and 90 watersheds respectively) to validate the classification. Watershed types corresponded with broad differences in streamflow regime, mean annual runoff, DOC seasonality, and mean DOC concentration. These links between watershed type and river conditions enabled the first region‐wide empirical characterization of river hydro‐biogeochemistry at the land‐sea margin, spanning extensive ungauged and unsampled areas. We found very high annual runoff (mean > 3,000 mm, n = 10) in three watershed types totaling 59,024 km2 and ranging from heavily glacierized mountain watersheds with high flow in summer to a rain‐fed mountain watershed type with high flow in fall‐winter. DOC hotspots (mean > 4 mg L−1, n = 14) were found in three other watershed types (48,557 km2) with perhumid rainforest climates and less‐mountainous topography. We described four patterns of DOC seasonality linked to watershed hydrology, with fall‐flushing being widespread. Hydro‐biogeochemical watershed classification may be useful for other complex regions with sparse observation networks.

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“…Terrestrial dissolved organic-matter-bound Fe, which likely predominates in these watersheds, has been shown to be highly stable during estuarine mixing and can be transported well beyond the estuary to open waters where it can serve as a source of potentially limiting Fe (Herzog et al, 2020b). However, despite this stability, these complexes remain permeable to microbial siderophores (Batchelli et al, 2010), molecules with a strong affinity for Fe that are produced by microbes across a wide diversity of nutrient regimes in the coastal oceans (Boiteau et al, 2019). The quantification of dFe complexation and more broadly of fate (sedimentation, uptake) is an important next step within this region (Fig.…”

Section: Role Of Freshwater Nutrient Inputs In Nearshore Ecosystemsmentioning

confidence: 99%

Rain-fed streams dilute inorganic nutrients but subsidise organic-matter-associated nutrients in coastal waters of the northeast Pacific Ocean

et al. 2021

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Abstract. In coastal regions, rivers and streams may be important sources of nutrients limiting to primary production in marine waters; however, sampling is still rarely conducted across the land-to-ocean aquatic continuum, precluding conclusions from being drawn about connectivity between freshwater and marine systems. Here we use a more-than-4-year dataset (2014–2018) of nutrients (nitrogen, phosphorus, silica, iron) and dissolved organic carbon spanning streams draining coastal watersheds and nearshore marine surface waters along the Central Coast of British Columbia, Canada, at the heart of the North Pacific coastal temperate rainforest region. Mean freshwater and surface marine N:Si:P ratios were 5:20:1 (P:Fe = 1:67) and 6:11:1, respectively, showing relative consistency across the land–ocean interface but deviation from the extended Redfield ratio. Inorganic nutrient concentrations (NO3-+NO2-, PO43-, Si(OH)4) in fresh waters were less than in the receiving marine environment, indicating that freshwater nutrient inputs in this region were of little importance to – or even diluted – the pool of readily available inorganic nutrients in nearshore waters. Conversely, fresh waters increased the pool of organic-matter-associated nutrients, namely dissolved organic nitrogen and iron. The organic-matter-rich landscapes of the region yielded globally significant quantities of dissolved organic nitrogen (304–381 kg km−2 yr−1) and iron (463–596 kg km−2 yr−1), thus acting as important sources of potentially limiting nutrients to both nearshore and offshore waters. These exports may subsidise heterotrophic microbial communities capable of directly consuming and remineralising these nutrients, potentially compensating for the dilution of inorganic nutrients by freshwater inputs. We highlight the need to better understand nutrient limitation in coastal waters and for concerted research efforts to study the spatial and temporal dynamism at the land–ocean interface along the northeast Pacific coast.

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Climate-Mediated Changes to Linked Terrestrial and Marine Ecosystems across the Northeast Pacific Coastal Temperate Rainforest Margin

Cited by 28 publications

References 108 publications

The Kwakshua Watersheds Observatory, central coast of British Columbia, Canada

The Kwakshua Watersheds Observatory, central coast of British Columbia, Canada

Watershed Classification Predicts Streamflow Regime and Organic Carbon Dynamics in the Northeast Pacific Coastal Temperate Rainforest

Rain-fed streams dilute inorganic nutrients but subsidise organic-matter-associated nutrients in coastal waters of the northeast Pacific Ocean

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