Abstract
Climate change is expected to warm, deoxygenate, and acidify ocean waters. Global climate models (GCMs) predict future conditions at large spatial scales, and these predictions are then often used to parameterize laboratory experiments designed to assess biological and ecological responses to future change. However, nearshore ecosystems are affected by a range of physical processes such as tides, local winds, and surface and internal waves, causing local variability in conditions that often exceeds global climate models. Predictions of future climatic conditions at local scales, the most relevant to ecological responses, are largely lacking. To fill this critical gap, we developed a 2D implementation of the Regional Ocean Modeling System (ROMS) to downscale global climate predictions across all Representative Concentration Pathway (RCP) scenarios to smaller spatial scales, in this case the scale of a temperate reef in the northeastern Pacific. To assess the potential biological impacts of local climate variability, we then used the results from different climate scenarios to estimate how climate change may affect the survival, growth, and fertilization of a representative marine benthic invertebrate, the red abalone Haliotis rufescens, to a highly varying multi-stressor environment. We found that high frequency variability in temperature, dissolved oxygen (DO), and pH increases as pCO2 increases in the atmosphere. Extreme temperature and pH conditions are generally not expected until RCP 4.5 or greater, while frequent exposure to low DO is already occurring. In the nearshore environment simulation, strong RCP scenarios can affect red abalone growth as well as reduce fertilization during extreme conditions when compared to global scale simulations.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.Introduction
With ocean temperatures expected to continue to rise, and dissolved oxygen (DO) and pH to decrease, due to climate change, there is an urgent need to understand how marine ecosystems will respond to future ocean conditions1,2,3. While the biological impacts of future variability in these, and other, co-occurring environmental drivers are not well understood, the few studies available suggest that understanding variability and covariation of multiple environmental stressors are important for predicting organism responses in marine ecosystems4,5. Currently, climate model predictions are generally global or regional in scale. However, the consequences of future environmental variability on species and ecological processes are predicated on local exposure regimes, which often exhibit higher temporal and spatial variability6,7,8,9 relative to global estimates. Therefore, there is a critical need to downscale global forecasts to biologically relevant local scales.
Global climate models (GCMs) predict increases in surface ocean temperature of up to 4 °C, declines in oxygen of up to 0.78 mg L−1, and reduction in pH of up to 0.35 units by 210010,11,12. One approach to understand how future global or regional predictions may manifest at local scales is to obtain higher spatio-temporal resolution estimates from GCMs through downscaling13. For example, downscaling of GCMs has been applied to resolve mesoscale oceanographic features. Using this approach, Busecke et al.14 recently showed that resolving mesoscale features (i.e. eddies) lead to a better representation of Equatorial Undercurrent (EUC) dynamics and the tilt of the Oxygen Minimum Zone (OMZ) in the Pacific, compared to 1° resolution results from a GCM. Downscaling has also been applied to understand how oceans will be affected by climate change at regional scales. In the California Current system (CCS)15, studies using downscaling approaches suggest by the year 2050 aragonite saturation state will decrease by 0.5–1 and the flux of nutrients, such NO3 (0.2 mmol-N m−3) and Si(OH)4 (0.8 mmol-Si m−3), will increase15,16. However, uncertainty in the ecosystem response in the CCS region remains due to the complexity of the environment, especially in nearshore ecosystems.
In the nearshore, tides, winds and waves (surface and internal) drive ocean dynamics9,17,18 at relatively small, short scales (i.e. < 1 km, < 24 h). Models that capture only mesoscale processes, and ignore local drivers, cannot resolve the dynamics of environmental conditions at biologically relevant spatial or temporal scales. For example, short term fluctuations in temperature, pH and DO that reach 5 °C, 0.5 pH units and 4 mg L−1 respectively at ~ 15 m depth in a ~ 13-h cycle (M2 tide) have been observed in Monterey Bay, CA, likely due to tidal forcing7 (Supplementary Fig. 1). In this system, nonlinear internal waves play an important role by advecting colder, low oxygen, and low pH waters into coastal ecosystems8,9, while large kelp forests contribute significant oxygen production and respiration that can alter local DO and pH dynamics19,20. However, current mesoscale oceanographic models that include Monterey Bay, CA do not capture these dynamics. Consequently, extrapolating future climate change scenarios to nearshore systems without simulation of high-frequency coastal processes such as diurnal winds, internal waves, tides, and consideration of biological process in the presence of this variability could drastically misrepresent associated ecosystem responses.
Adding to the complexity in predicting ecosystem responses under future climate scenarios; marine organisms often exist close to their tolerance limits and thus deviations of temperature, DO, and pH from natural background conditions can cause physiological stress21. Moreover, multi-stressor responses may differ from the aggregate of single stressor predictions, with both synergistic and antagonistic interactions frequently occurring22. For example, low DO and low pH act synergistically to reduce the survival and growth of juvenile red abalone (Haliotis rufescens)23, while increased temperature counteracts the negative impacts of low pH on fertilization rates in the same species23. Such interactions suggest that understanding how temperature, DO, and pH co-vary and how these conditions affect the local biota is critical for predicting biological responses to climate change3,9,24,25. Here, we show how variability in co-varying environmental drivers (T, DO, pH) may change under future conditions (increasing levels of CO2) and how these scenarios affect exposure of nearshore organisms to potentially stressful conditions. To do so, we developed and calibrated an idealized coupled biogeochemical hydrodynamic model using in situ data from the upwelling period in the region of southern Monterey Bay near Hopkins Marine Station, Pacific Grove, CA USA (Fig. 1). We then used a downscaling approach for Representative Concentration Pathway (RCP) scenarios for the year 2100 as boundary and initial conditions in the model and estimated the potential effect on growth and fertilization for the red abalone, Haliotis rufescens. H. rufescens was chosen because there is extensive experimental data available on the interactive effects of environmental stressors on their growth and fertilization. Red abalone also represent a variety of benthic calcifying marine invertebrates with a motile larval stage and sedentary post-settlement stages, and have important economic value26.
Methods
Study region
Monterey Bay is the largest bay on the California coast, and has a total area of approximately 1,162 km2 (Fig. 1). Due to upwelling, the bay is highly productive and supports dense kelp forests, dominated by Macrocystis pyrifera, on rocky reefs that extend to approximately 20 m depth27. These forests have the capacity to regulate pH28,29,30 and sustain over 200 different species, from phytoplankton to marine mammals31.
Temperatures are the coolest in Monterey Bay during spring and early summer due to wind-driven upwelling32, driven by equatorward winds blowing over the California coast causing offshore Ekman transport33. During the same months, filaments of water originating from Point Año Nuevo to the north are trapped within the Bay, where they warm due to solar radiation, forming a lens of warm water close to shore34,35 (Fig. 1). Furthermore, a weak cyclonic eddy is observed within the bay due to the coastal geometry32,34. Inside the bay, sea breezes and tides drive diurnal and semi-diurnal currents that can lead to significant variability in environmental conditions17,36. During the upwelling period, salinity is approximately 34, temperature ranges from 9 to 13 °C at 17 m depth7, DO varies from as low as 100 μmol kg−1 (3.2 mg L−1 for T = 13 °C, S = 34 at 17 m) to as high as 300 μmol kg−1 (9.62 mg L−1 for T = 13 °C, S = 34 at 17 m), and pH varies from 7.7 to 8.13 (Supplementary Fig. 1).
The three primary barotropic tidal constituents in the region (M2, K1, and S2) are responsible for over 80% of the tidal amplitude observed18. In the southern region of the bay, tides are mainly responsible for the cross-shelf velocity36 and the interaction of these surface tidal currents with the steep topography create internal tides comprised of internal waves and bores occurring at tidal frequencies37,38. Internal tides are formed when currents move over steep slopes, dense waters are forced into shallower regions, and, as these waters sink back to depth, an internal wave is generated39. These internal waves have speeds8 on the order of 0.05–0.2 m s−1 and, as the coast steepens, can break forming internal bores that move upslope and bring cold, low DO, low pH waters into nearshore kelp forest ecosystems40. During upwelling, these processes drive variability in temperature, pH and DO over semi-diurnal and diurnal periods that can exceed the predicated changes in mean conditions predicted by global climate models for year 210041.
Model description
To better understand how tides and winds affect exposure of nearshore organisms to variability in temperature, DO, and pH under current and RCP climate scenarios, we used dynamic downscaling and developed a 2D coupled biogeochemical hydrodynamic model using ROMS42. The model domain was created based on the Monterey Bay continental shelf described in Walter et al.6 with a maximum offshore depth of approximately 80 m (Fig. 2). The biogeochemical model used is described in Fennel et al.43,44. We forced the model with representative wind (diurnal sea breeze accounting for regional winds), solar radiation, and tidal currents for the Monterey Bay region (Supplementary Figs. 2–6; Supplementary Table 1). Detail of the full model structure, including boundary and initial conditions, are included in the “Supplementary Information”.
We estimated depth profiles for temperature, DO, and pH for the downscaled coupled hydrodynamic-biogeochemical model. We considered a homogeneous salinity (S = 34) for the entire domain since the variation in salinity is less than 0.4 over an entire year and less than 0.05 during the upwelling season in the Monterey Bay region27. Thus, initial and boundary stratification are assumed to be controlled by temperature alone. We represent initial (IC) and boundary conditions (BC) for temperature, DO, and pH using:
where var is the identified variable (e.g. temperature), z is the depth, α is a fit coefficient for each variable determined from a least-squares fit to observational data, and Dpyc is the depth of the pycnocline. We used this method to estimate profiles of temperature, dissolved inorganic carbon (DIC), and DO for present and all downscaled future scenarios setting Dpyc to 17.5 m. The data used for the initial and boundary conditions (BC) of phytoplankton and chlorophyll profiles were taken from Schuckmann et al.45. The initial chlorophyll concentration was converted to zooplankton concentration (zoop = 0.34 × 10–3 mmol m−3) using Eq. 3 from Wiebe46, a method that has been used in other studies47,48. Detritus was initially set to zero in the entire domain. All biogeochemical variables were forced hourly at the southern boundary.
For each scenario, we estimated depth profiles for temperature, dissolved oxygen, and DIC using Eq. (1). In order to fit Eq. (1), we obtained our estimated values of each variable near the surface, at 80 m depth on the shelf during upwelling for Present and 200 m depth for Future, respectively. We used 200 m depth from the future data set as this is the most common depth of source waters for upwelling in the region49. Present surface and bottom values of temperature, DO, total alkalinity (TA), and DIC for present scenario were based on Koweek et al.27. The mean of the 3-month period of strong upwelling (May, June, and July) was used to obtain values of temperature (surface and depth), oxygen (surface), and DIC (surface) from Representative Concentration Pathway (RCP) for the year of 2100 from the 4th report of the IPCC50. Since only surface values for DO and DIC and no values for TA were available, we estimated values for these parameters at depth.
For DIC, we assumed that the ratio between surface and bottom values (80 m for Present and 200 m for Future) in present conditions will not change for future scenarios:
Therefore, to find the bottom values for future scenarios we divided RCP surface values by this ratio:
Surface and bottom TA values were kept the same as present conditions, following Feely et al.3. For DO, bottom values for RCP 2.6 and 8.5 were approximated from Figs. 5 and 6 of Bopp et al.51. We calculated the ratios between surface and bottom DO for Present, RCP 2.6, and RCP 8.5. The ratio of surface:bottom DO was not constant across scenarios, so we approximated the ratios for RCPs 4.5 and 6.0 using linear least squares fit (Table 1; example calculation in the “Supplementary Information”). We, then applied the values from Table 1 in order to calculate α assuming Dpyc = 17.5 m. We then used Eq. (1) to generate the initial and boundary conditions (Fig. 3).
We calculated pH and Ωar using the CO2SYS52 package in MATLAB using temperature, salinity, DIC, and Total Alkalinity (TA) from the simulations at the offshore location where the bottom depth was 15 m. We assumed concentrations of phosphate and silica based on Koweek et al.27. We used dissociation constants for H2CO3 and HCO3 from Dickson and Millero53 and hydrogen sulfate ion constant (HSO-4) from Dickson54. All surface oxygen values were shifted positively 60 mmol m−3 (1.87 mg L−1 for T = 13 °C and S = 34) in order to simulate the high primary production due to kelp forests29, which is not specifically accounted for in the model. Overall, temperature at the bottom remained constant across all scenarios, with exception of RCP6.0 where temperature increased 0.2 °C (Supplementary Table 2).
Integrated exposure
Field observations24,55 and laboratory experiments5,56 have shown that below sub-lethal thresholds marine organisms inhabiting nearshore marine habitats in upwelling systems exhibit signs of physiological stress when exposed to elevated temperatures, low oxygen levels, or low pH waters, which is especially detrimental especially for calcifying species. Exposure of organisms to stressful temperature, DO, and pH conditions (φth where φ refers to temperature, DO, or pH) was done by subtracting the threshold value for a given organism and life stage from the model or observational data at 15 m water depth, then setting all positive values to zero for pH and O2, and all negative values to zero for temperature. Next, we estimated integrated exposure (Eint) by integrating absolute exposure over a period of a week with a window interval of 1 h:
Thresholds of temperature, dissolved oxygen and pH (16 °C57, 4.8525 mg L−1, and pH of 7.523 respectively) representing non-interactive negative impacts on juvenile red abalone growth were based on literature values5,23,57. Integrated exposure quantified the time and degree of stress an organism experiences, similar to the degree heating week with units of oC w, or day (oC d) measure used to estimate thermal stress on coral reefs58, and has been previously used to understand the exposure of juvenile abalone populations to similar stressors in an empirical field study57. Overall, red abalone threshold values chosen had a strong negative effect on the species5,23,57, therefore, we used Eint as a proxy for estimating the potential impact of future conditions on abalone growth and survival.
Fertilization response
We estimated fertilization success using results of Boch et al.25 where the fertilization response of red abalone (Haliotis rufescens) was quantified in response to multiple stressor climate conditions (high temperature, low DO, and low pH). Fertilization in abalone occurs over relatively short periods, therefore Eint would not provide an appropriate estimate in such cases. While the process of fertilization occurs over short periods, adult red abalone exhibit an extended spawning season, over which environmental conditions may vary greatly based on our modeling results. Thus, we used the equations from Boch et al.25 to examine how fertilization success over a one-month period might be affected by environmental variability, specifically the interactive effects of ph and temperature. Changes in DO did not show a strong effect on fertilization in their experiments (Fig. 4; see Supplementary Table 3 for parameter values):
For temperatures = 13 °C:
For Temperatures = 18 °C:
where \({\upbeta }_{0}\) and \({\upbeta }_{\mathrm{pH}}\) are intercepts, \(\upbeta \) and \({\upbeta }_{2}\) are slope segments, \({\upbeta }_{\mathrm{A}}\) is slope of the pH-temperature interaction (pH × Temperature Group), \({\upbeta }_{\mathrm{B}}\) is accounts for high temperature effects, and BP is the curve breaking point. Since only curves for 13 °C and 18 °C were available, we used 15.5 °C as a transition where Eq. (5) was applied for temperature less than 15.5 °C and Eq. (6) was applied for temperature greater than 15.5 °C. Since more complex interpolation schemes yielded similar results, we used this straightforward method for clarity.
Model evaluation
We first assessed whether the oceanographic model was able to reproduce current (observed) oceanographic conditions in Monterey Bay. The model was expected to reproduce the main dominant semi-diurnal and diurnal periods of oscillations observed in the region as well as primary production regulation of DO and pH (excluding kelp) in the biogeochemical model. We had two requisites to consider the model performance satisfactory. First, we required that the model was capable of reproducing local minima for DO. Second, the model needed to be capable of reproducing the mean and extremes for temperature and pH. In addition, we anticipated observing lower values of DO in surface waters since we did not account for the higher primary productivity observed in kelp forests20, and therefore, DO oversaturation. To evaluate the biogeochemical model, we compared chlorophyll concentration in the model to satellite-derived chlorophyll estimates for the region. Monthly mean depth averaged chlorophyll by area (mg Chl m−1) was calculated for the model and for the months of May, June, and July from Sea-Viewing Wide Field-of-View Sensor (SeaWiFS)59 for the period of 2010–2017 to the closest region with data available next to our model simulation (cross section region in Fig. 1). Chlorophyll concentrations in the model were 2.12 mg Chl m−3 compared to 4.02 mg Chl m−3 estimated from SeaWifs. Thus, modeled values were within the range observed in the satellite data over this period.
In order to validate temporal variability in the model results, we estimated power spectra using the Thomson Multi-taper method (MTM)60. This method was chosen due to its robustness for stationary data with low variance. Power spectra allowed us to quantify the variability by frequency and confirm that the model was reproducing variability at dominant periods (M2, K1) observed in the region, as initial and boundary conditions in the model were based on regional observations. We applied the analysis over a 3-week window of upwelling for temperature, DO, and pH and compared with Booth et al.7 data (Fig. 5). Spectral analysis was used to ascertain the dominate temporal constituents of temperature, DO, and pH for all scenarios (present and RCP) between 12- and 24-h periods. The spectra were then integrated numerically to calculate the variability of temperature, DO, and pH, and the 95% confidence interval at each frequency band. Bootstrap analysis was applied to the integrated exposure calculation for each variable. In order to assure convergence in our estimates, 1,000 iterations with replacement were done using a sample size of 50% of the data. In the end, the confidence interval (CI) was calculated based on 2.5% percentile and 97.5% percentile of the distribution of the estimated means.
Our model results reflect current variability in temperature, DO, and pH in southern Monterey Bay (Fig. 5). In addition, mean temperature and pH values were not significantly different from in situ data. However, mean DO in our model was lower than present day averages, likely due to the lack of oxygen-producing kelp in our model61. Thus, the model accurately simulates diurnal, semi-diurnal, and higher order tidal components62. For Monterey Bay, diurnal (cycles per day (cpd) = 1) and semi-diurnal (cpd = 1.93) are the main temporal components of variability in temperature, oxygen, and pH and are well represented by our model with overlapping 95% confidence intervals (Fig. 5b,d,f). Higher frequency variability (cpd = 3) is also within the 95% confidence interval when comparing model and observations. However, frequencies occurring between peaks are not well resolved (Fig. 5b,d,f). We expect this is because we used a 2D model, and therefore, the model was unable to resolve all the physical processes occurring in the Monterey Bay. The oscillations between peaks in the observed data were likely due other coastal ocean processes such 3D circulation and ocean surface waves36 (as well as noise in the instruments). However, the variability at these periods did not have an appreciable effect on exposure calculations. Importantly, the model preserved the observed diurnal and semi-diurnal variability that is not present in global and regional scale climate models for future RCP scenarios (Fig. 5a,c,e).
Variability at 15 m
The model was able to simulate the main drivers of variability in temperature, DO, and pH (predominantly internal waves) for the region in study. Internal waves in the domain were seen as vertical changes in the u-component of the velocity (Fig. 2). Cross-shelf velocities ranged from − 0.05 to 0.1 m s−1, and were within the range found in other studies8,18,27. Before the arrival of the internal wave crest, isotherms were tilted downwards indicating previous downwelling. Flow in opposite directions between crests was observed during retreating of internal waves in the domain, as it has been observed in studies on internal waves with in situ data8,9.
High variability in temperature, DO, and pH was observed in all model runs (Supplementary Figs. 7–9). Mean temperatures were 10.63 °C (SD = 0.39), 13.81 °C (SD = 0.46), 15.46 °C (SD = 0.50), 15.45 °C (SD = 0.49), 16.96 °C (SD = 0.95) for present, RCP 2.6, RCP 4.5, RCP 6.0, and RCP 8.5, respectively (Supplementary Fig. 7). Overall, mean temperature increased as expected and exhibited similar variability (standard deviation [SD]) across all RCPs except for RCP 8.5 scenario. This was likely due to increased temperature stratification where surface waters warm faster than deeper waters resulting in higher temperature variability.
Mean dissolved oxygen values were 5.15 mg L−1 (SD = 0.74) for present, 4.80 mg L−1 (SD = 0.88) for RCP 2.6, 5.32 mg L−1 (SD = 0.77) for RCP 4.5, 5.02 mg L−1 (SD = 0.81) for RCP 6.0, and 4.93 mg L−1 (SD = 1.21) for RCP 8.5 (Supplementary Fig. 8). The SD for RCP 8.5 was almost twice that of other scenarios. This was likely due to a stronger gradient in oxygen (surface remains saturated while the values at depth are lower). RCP 2.6 had the lowest mean DO but not different than the rest and RCP 4.5 was 0.52 mg L−1 higher, though not significantly different than the present scenario. The consequence for the lowest mean DO in RCP 2.6 was related to the strength of density stratification61, and therefore, low oxygen at 15 m. Another scenario (not shown) was used where RCP 4.5 oxygen profile was applied using the density stratification from RCP 2.6 and the same low oxygen values found previously were also observed in the alternate run, supporting this mechanism.
pH variability was also high across all model runs (Supplementary Fig. 9). The mean value for pH decreased from 7.73 (SD = 0.07) for present to 7.44 (SD = 0.12) for the RCP 8.5 scenario. RCP 8.5 again had the highest variability among all scenarios. Otherwise, the pH range was ~ 0.075 for all other scenarios. Lower pH for the most extreme scenarios (RCP 6.0 and 8.5) has also been observed in large scale models12.
Results and discussion
Here, we focus on the estimated effects on growth (integrated exposure) and fertilization rates for red abalone (Figs. 6, 7). Integrated mean daily exposure (hereafter 'exposure') to potential stressors individually showed a positive trend from present to RCP 8.5 for all three environmental parameters (Fig. 6b,d,f). Exposure to Present in situ conditions showed similar exposure when compared to our simulated Present exposure with the only significant difference in the exposure to low DO. Exposure of juvenile red abalone to high temperature increased approximately linearly from none at present to 1.11 °C day in RCP 8.5. Similarly, exposure to low DO showed a trend across RCPs (Fig. 6d), where variability in mean daily exposure was highest (SD = 0.068 mg L−1 day) in RCP 8.5. Exposure to low pH was generally low except in the last two scenarios (0.106 and 0.166 pH d for RCP 6.0 and RCP 8.5, respectively) (Fig. 6f). Variability in pH exposure also increased over all RCPs, and was highest for RCP 8.5 scenario (SD = 0.020 pH day).
To quantify the interactive effects of multiple stressors on red abalone fertilization success, we used functional relationships from Boch et al.25 for temperature and pH to predict the proportion of fertilized gametes hourly over a 6-week period. Fertilization success (hereafter fertilization) showed wide variation across all RCP scenarios (Fig. 7). Mean fertilization rate only decreased for red abalone in RCP 6.0 and 8.5. This pattern was also observed for integrated pH exposure (Fig. 6f). For the present through RCP 4.5 scenarios, the pH was in the range of moderate fertilization success (pH > 7.5, Boch et al.25) and temperatures had little effect. In RCPs 6.0 and 8.5, pH was low enough (< 7.5) that often fertilization success was extremely low (< 0.25), however temperatures were often warm enough to keep fertilization in the same range of the other scenarios (0.4–0.5). Although we found that future changes in the environmental drivers could be stressful to abalone, higher temperatures often counteract the effect of pH on fertilization for red abalone25.
Present environmental variability in the nearshore can be larger than the total mean change predicted by large-scale climate models by the year 210041. Using idealized tidal and wind patterns, our downscaled model captures the present observed variability in environmental drivers at diurnal and semi-diurnal frequencies in Monterey Bay, demonstrating the model’s ability to account for local processes which ultimately govern climatic variability at small scales. The importance of this downscaling approach in estimating potential biological impacts of future climate change is demonstrated by the comparing the predicted impacts on abalone fertilization and juvenile growth from our model versus those from the large-scale model, for a given RCP scenario (Table 2). Our results suggest that predicted impacts on red abalone growth and fertilization based on RCP 8.5 (non-upwelling) and RCP 8.5 (upwelling) are either under or overestimates, relative to the predictions based on the 2D model, demonstrating the need for downscaled models to estimate ecological impacts in nearshore systems under future climate change. The need for downscaled models is more important when considering the stress imposed on organisms due to frequent changes in conditions. For example, abalone may adapt to a constant elevated mean temperature, but not to rapidly fluctuating elevated temperatures.
In addition to demonstrating the importance of accounting for local processes in determining future climatic variability at small nearshore scales, this study highlights that future biological impacts may vary significantly across life stages. For red abalone fertilization is vulnerable to pH25, though this response is mediated by the ambient temperature. Therefore, fertilization in future climate scenarios could show either no effect or completely fail due to pH depending on the ambient temperature. In a future nearshore ocean with high environmental variability, timing of gamete release could be crucial in determining fertilization success. Benthic organisms such as abalone will experience effects on growth only in a few of the scenarios simulated using our downscaling approach (RCP 6.0, 8.5 for temperature, RPC 8.5 for DO, and 4.5 and on for pH), scenarios where elevated temperatures predicted by our downscale model could help ameliorate the negative impacts of pH on fertilization23.
Our study illustrates how the high temporal and short spatial scale oceanographic processes in the nearshore environments can have significant effects on the exposure of organisms to climate-related stressors. Our results also demonstrate that laboratory experiments investigating the effects of climate change scenarios on benthic organisms must include high frequency variability, both current and predicted future, and determine the interactive effects of environmental drivers in order to determine how marine ecosystems, and the organisms that comprise them will respond to future conditions. Our methodology could be (1) generalized to regions within other upwelling ecosystems with high diurnal and semi-diurnal variability61,63, (2) used to estimate future biological effects for species, beyond abalone, where environmental thresholds are established, and (3) applied to design experiments to identify species-specific thresholds to future in situ environmental conditions. However, the downscaled model assumes that ocean stratification, wind patterns, and biochemical rates will not change by the end of twenty-first century, and therefore, these predictions should be tested in future studies.
References
McClatchie, S., Goericke, R., Cosgrove, R., Auad, G. & Vetter, R. Oxygen in the Southern California Bight: Multidecadal trends and implications for demersal fisheries. Geophys. Res. Lett. 37, 1–5 (2010).
Deutsch, C., Brix, H., Ito, T. & Thompson, L. Climate-forced variability of ocean hypoxia. Science (80-). 333, 336–339 (2011).
Feely, R. A. et al. The combined effects of acidification and hypoxia on pH and aragonite saturation in the coastal waters of the California current ecosystem and the northern Gulf of Mexico. Cont. Shelf Res. 152, 50–60 (2018).
Comeau, S. et al. Resistance to ocean acidification in coral reef taxa is not gained by acclimatization. Nat. Clim. Chang. 9, 477–483 (2019).
Low, N. H. N. & Micheli, F. Lethal and functional thresholds of hypoxia in two key benthic grazers. Mar. Ecol. Prog. Ser. 594, 165–173 (2018).
Johnson, K. S. Simultaneous measurements of nitrate, oxygen, and carbon dioxide on oceanographic moorings: Observing the Redfield ratio in real time. Limnol. Oceanogr. 55, 615–627 (2010).
Booth, J. A. T. et al. Natural intrusions of hypoxic, low pH water into nearshore marine environments on the California coast. Cont. Shelf Res. 45, 108–115 (2012).
Walter, R. K., Woodson, C. B., Leary, P. R. & Monismith, S. G. Connecting wind-driven upwelling and offshore stratification to nearshore internal bores and oxygen variability. J. Geophys. Res. Ocean. 119, 3517–3534 (2014).
Woodson, C. B. The fate and impact of internal waves in nearshore ecosystems. Ann. Rev. Mar. Sci. 10, 421–441 (2018).
Stocker, G. et al. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (Cambridge Univ. Press, 2013).
Bopp, L., Resplandy, L., Untersee, A., Le Mezo, P. & Kageyama, M. Ocean (de)oxygenation from the Last Glacial Maximum to the twenty-first century: Insights from Earth System models. Philos. Trans. R. Soc. A Math. Phys. Eng. Sci. 375, 1–15 (2017). https://doi.org/10.1098/rsta.2016.0323.
Kwiatkowski, L. & Orr, J. C. Diverging seasonal extremes for ocean acidification during the twenty-first century. Nat. Clim. Chang. 8, 141 (2018).
Xu, Z. & Yang, Z. L. An improved dynamical downscaling method with GCM bias corrections and its validation with 30 years of climate simulations. J. Clim. 25, 6271–6286 (2012).
Busecke, J. J. M., Resplandy, L. & Dunne, J. P. The equatorial undercurrent and the oxygen minimum zone in the Pacific. Geophys. Res. Lett. https://doi.org/10.1029/2019GL082692 (2019).
Gruber, N. et al. Rapid progression of ocean acidification in the California Current System. Science (80-). 337, 220–223 (2012).
Xiu, P., Chai, F., Curchitser, E. N. & Castruccio, F. S. Future changes in coastal upwelling ecosystems with global warming: The case of the California Current System. Sci. Rep. 8, 1–9 (2018).
Woodson, C. B. et al. Local diurnal upwelling driven by sea breezes in northern Monterey Bay. Cont. Shelf Res. 27, 2289–2302 (2007).
Carter, G. S. Barotropic and Baroclinic M 2 Tides in the Monterey Bay Region. J. Phys. Oceanogr. 40, 1766–1783 (2010).
Behrenfeld, M. J. & Falkowski, P. G. Photosynthetic rates derived from satellite-based chlorophyll concentration. Limnol. Oceanogr. 42, 1–20 (1997).
Laffoley, D. & Grimsditch, G. (eds) The Management of Natural Coastal Carbon Sinks (IUCN, 2009).
Somero, G. N. The physiology of global change: Linking patterns to mechanisms. Ann. Rev. Mar. Sci. 4, 39–61 (2012).
Crain, C. M., Kroeker, K. & Halpern, B. S. Interactive and cumulative effects of multiple human stressors in marine systems. Ecol. Lett. 11, 1304–1315 (2008).
Kim, T. W., Barry, J. P. & Micheli, F. The effects of intermittent exposure to low-pH and low-oxygen conditions on survival and growth of juvenile red abalone. Biogeosciences 10, 7255–7262 (2013).
Frieder, C. A., Gonzalez, J. P., Bockmon, E. E., Navarro, M. O. & Levin, L. A. Can variable pH and low oxygen moderate ocean acidification outcomes for mussel larvae?. Glob. Chang. Biol. 20, 754–764 (2014).
Boch, C. A. et al. Effects of current and future coastal upwelling conditions on the fertilization success of the red abalone (Haliotis rufescens). ICES J. Mar. Sci. 74, 1125–1134 (2017).
Zippay, M. L. & Hofmann, G. E. Effect of pH on gene expression and thermal tolerance of early life history stages of red abalone (Haliotis rufescens). J. Shellfish Res. 29, 429–439 (2010).
Koweek, D. A. et al. A year in the life of a central California kelp forest: Physical and biological insights into biogeochemical variability. Biogeosciences 14, 31–44 (2017).
Miller, R. J., Reed, D. C. & Brzezinski, M. A. Partitioning of primary production among giant kelp (Macrocystis pyrifera), understory macroalgae, and phytoplankton on a temperate reef. Limnol. Oceanogr. 56, 119–132 (2011).
Reed, D. C. et al. Wave disturbance overwhelms top-down and bottom-up control of primary production in California kelp forests. Ecology 92, 2108–2116 (2011).
Krause-Jensen, D. et al. Long photoperiods sustain high pH in Arctic kelp forests. Sci. Adv. 2, e1501938 (2016).
Graham, M. H. Effects of local deforestation on the diversity and structure of southern california giant kelp forest food webs. Ecosystems 7, 341–357 (2004).
Tseng, Y. H., Dietrich, D. E. & Ferziger, J. H. Regional circulation of the Monterey Bay region: Hydrostatic versus nonhydrostatic modeling. J. Geophys. Res. C Ocean. 110, 1–21 (2005).
Huyer, A. Coastal upwelling in the California current system. Prog. Oceanogr. 12, 259–284 (1983).
Breaker, L. C. & Broenkow, W. M. The circulation of Monterey Bay and related processes. Oceanogr. Mar. Biol. 32, 1–64 (1994).
Rosenfeld, L. K., Schwing, F. B., Garfield, N. & Tracy, D. E. Bifurcated flow from an upwelling source: A cold water source for Monterey Bay. Cont. Shelf Res. 14, 931–964 (1994).
Woodson, C. B. Spatiotemporal variation in cross-shelf exchange across the inner shelf of Monterey Bay. California. J. Phys. Oceanogr. 43, 1648–1665 (2013).
Garrett, C. Internal tides and ocean mixing. Science (80-). 301, 1858–1859 (2003).
Dettner, A., Swinney, H. L. & Paoletti, M. S. Internal wave and boundary current generation by tidal flow over topography. Phys. Fluids 25, 116601 (2013).
Pugh, D. & Woodworth, P. Sea-Level Science: Understanding Tides, Surges, Tsunamis, and Mean Sea Level (Cambridge University Press, Cambridge, 2014). https://doi.org/10.1017/CBO9781139235778
Martini, K. I., Alford, M. H., Kunze, E., Kelly, S. M. & Nash, J. D. Internal bores and breaking internal tides on the oregon continental slope. J. Phys. Oceanogr. 43, 20–139 (2012).
Leary, P. R. et al. “Internal tide pools” prolong kelp forest hypoxic events. Limnol. Oceanogr. 62, 2864–2878 (2017).
Haidvogel, D. B. et al. Ocean forecasting in terrain-following coordinates: Formulation and skill assessment of the Regional Ocean Modeling System. J. Comput. Phys. 227, 3595–3624 (2008).
Fennel, K. et al. Nitrogen cycling in the Middle Atlantic Bight: Results from a three-dimensional model and implications for the North Atlantic nitrogen budget. Glob. Biogeochem. Cycles 20, 1–14 (2006).
Fennel, K., Wilkin, J., Previdi, M. & Najjar, R. Denitrification effects on air-sea CO2 flux in the coastal ocean: Simulations for the northwest North Atlantic. Geophys. Res. Lett. 35, 1–5 (2008).
Schuckmann, K. V. et al. The copernicus marine environment monitoring service ocean state report. J. Oper. Oceanogr. 9, 1755–8778 (2016).
Wiebe, P. H. Functional regression equations for zooplankton displacement volume wet weight, dry weight, and carbon: A correction. Fish. Bull. 86, 833–835 (1988).
Strömberg, K. H. P., Smyth, T. J., Allen, J. I., Pitois, S. & O’Brien, T. D. Estimation of global zooplankton biomass from satellite ocean colour. J. Mar. Syst. 78, 18–27 (2009).
O'Brien, T. Copepod: A global plankton database. US Dep. Commerce, NOAA Tech. Memo. NMFS-F/SPO-73, 136 (2005).
Jacox, M. G. & Edwards, C. A. Effects of stratification and shelf slope on nutrient supply in coastal upwelling regions. J. Geophys. Res. Ocean. 116, 1–17 (2011).
IPCC. Summary for Policymakers. Climate Change 2013: The Physical Science Basis. Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (Cambridge University Press, Cambridge, 2013). https://doi.org/10.1017/CBO9781107415324.004
Bopp, L. et al. Multiple stressors of ocean ecosystems in the 21st century: Projections with CMIP5 models. Biogeosciences 10, 6225–6245 (2013).
Lewis, E. & Wallace, D. W. R. Program developed for CO2 system calculations. ORNL/CDIAC-105 (Carbon Dioxide Information Analysis Center, Oak Ridge National Laboratory, US Department of Energy, Oak Ridge, Tennessee, 1998).
Dickson, A. G. & Millero, F. J. A comparison of the equilibrium constants for the dissociation of carbonic acid in seawater media. Deep Sea. Res. Part A, Oceanogr. Res. Pap. 34, 1733–1743 (1987).
Dickson, A. G. Standard potential of the reaction: AgCl(s) + 1/2 H2(g) = Ag(s) + HCl(aq), and the standard acidity constant of the ion HSO4- in synthetic sea water from 273.15 to 318.15 K. J. Chem. Thermodyn. 22, 113–127 (1990).
Suanda, S. H., Barth, J. A. & Woodson, C. B. Diurnal heat balance for the northern Monterey Bay inner shelf. J. Geophys. Res. Ocean. 116, 1–13 (2011).
Resplandy, L. et al. Multiple stressors of ocean ecosystems in the 21st century: Projections with CMIP5 models. Biogeosciences 10, 6225–6245 (2013).
Boch, C. A. et al. Local oceanographic variability influences the performance of juvenile abalone under climate change. Sci. Rep. 8, 1–12 (2018).
Liu, G. et al. Reef-scale thermal stress monitoring of coral ecosystems: New 5-km global products from NOAA coral reef watch. Remote Sens. https://doi.org/10.3390/rs61111579 (2014).
NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Ocean Biology Processing Group. (2014): Sea-viewing Wide Field-of-view Sensor (SeaWiFS) Ocean Color Data, NASA OB.DAAC. https://doi.org/10.5067/ORBVIEW-2/SEAWIFS_OC.2014.0. Accessed on 25 Mar 2020.
Thomson, D. J. Spectrum estimation and harmonic analysis. Proc. IEEE 70, 1055–1096 (1982).
Frieder, C. A., Nam, S. H., Martz, T. R. & Levin, L. A. High temporal and spatial variability of dissolved oxygen and pH in a nearshore California kelp forest. Biogeosciences 9, 3917–3930 (2012).
Chan, F. et al. Persistent spatial structuring of coastal ocean acidification in the California Current System. Sci. Rep. 7, 1–7 (2017).
Hofmann, G. E. et al. High-frequency dynamics of ocean pH: A multi-ecosystem comparison. PLoS One 6, 1–11 (2011).
Acknowledgements
We gratefully acknowledge support by NSF Grants OCE-1416934 and OCE-1736830. Also, we would like to thank the editor and anonymous reviewers for the suggestions to improve the paper.
Author information
Authors and Affiliations
Contributions
C.B.W. designed the study. M.F. conducted model runs. M.F. and C.B.W. analyzed the data. F.M, S.Y.L., G.L., C.A.B., J.P.B., and S.O. contributed significantly with constructive feedback to the science and internal discussions of the manuscript.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Fagundes, M., Litvin, S.Y., Micheli, F. et al. Downscaling global ocean climate models improves estimates of exposure regimes in coastal environments. Sci Rep 10, 14227 (2020). https://doi.org/10.1038/s41598-020-71169-6
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-020-71169-6
- Springer Nature Limited
This article is cited by
-
Linking the long-term variability in global wave energy to swell climate and redefining suitable coasts for energy exploitation
Scientific Reports (2022)
-
Reef larval recruitment in response to seascape dynamics in the SW Atlantic
Scientific Reports (2022)