Climate and landform interact to control the source and transport of nitrate in Pacific Northwest rivers

Abstract

The hydrological effects of climate change are documented in many regions; however, climate-driven impacts to the source and transport of river nutrients remain poorly understood. Understanding the factors controlling nutrient dynamics across river systems is critical to preserve ecosystem function yet challenging given the complexity of landscape and climate interactions. Here, we harness a large regional dataset of nitrate (NO₃^–) yield, concentration, and isotopic composition (δ¹⁵N and δ¹⁸O) to evaluate the strength of hydroclimate and landscape variables in controlling the seasonal source and transport of NO₃^–. We show that hydroclimate strongly influenced the seasonality of river NO₃^–, producing distinct, source-dependent NO₃^– regimes across rivers from two mountain ranges. Riverine responses to hydroclimate were also constrained by watershed-scale topographic features, demonstrating that while regional climate strongly influences the timing of river NO₃^– transport, watershed topography plays a distinct role in mediating the sensitivity of river NO₃^– dynamics to future change.

Introduction

Rivers and streams play a critical role in regional nitrogen (N) cycles through the transport and in situ processing of dissolved reactive N as it moves from the land to the coast¹. Dramatic increases in the load of N to freshwaters from human activities have stressed the bounds of riverine N processes, fundamentally altering patterns of riverine N transport, and exacerbating eutrophication in freshwaters and estuaries^2,3,4. Despite substantial investment to reduce watershed N loads to rivers, anthropogenic activity and land use change continue to elevate N sources across the landscape⁵. Furthermore, as climate change strengthens precipitation patterns, hydroclimatic shifts are projected to alter the seasonal timing and delivery of NO₃^– (frequently the dominant form of dissolved N) from watersheds to rivers and streams⁶. Understanding the factors controlling seasonal river NO₃^– variation is critical to evaluate impacts downstream, but the balance of landscape and hydroclimatic variables in driving the N export dynamic remains unclear.

For any river system, landscape features represent a potentially dominant driver of instream NO₃^– concentrations and NO₃^– yields^7,8,9,10,11. Specifically, geomorphic attributes, such as watershed slope, channel morphology, and floodplain area, determine water residence times and hydrologic connectivity, ultimately governing watershed NO₃^– retention, loss (via biotic uptake or denitrification), and movement from watersheds to rivers and streams^{9,10,11,12,13}. Such catchment characteristics also influence the source composition and availability of NO₃^– by determining the structure and composition of vegetation and soils, and by constraining the spatial distribution of human activity. In watersheds with steep slopes, catchment topography limits human activity, restricting NO₃^– source composition to nitrified soil ammonium (NH₄⁺) and atmospheric deposition^14,15. Lower sloped areas instead increase space for human development, agricultural activity, and the growth of N-fixing species (such as alders, Alnus spp.)¹⁵, promoting the accumulation of N in soils and groundwater, enhancing the transport potential of NO₃^–16,17. Spatial and temporal variation of river NO₃^– is further controlled by seasonal precipitation patterns and river flow, which mobilize NO₃^– from the landscape and drive the timing and magnitude of NO₃^– transport across systems^18,19.

Characterizing how different landscape and hydroclimatic controls transport or retain nutrients is important to improve the understanding of future river NO₃^– exports, but difficult due to the multiple scales at which drivers operate and the complex interactions they produce^20,21,22. For instance, current ecological stressors, such as changing land use and climate change, are global in scale with impacts that propagate differently across ecosystems^19,23. In riverine environments, climate-induced shifts to the quantity and form (rain vs. snow) of precipitation will alter the timing and magnitude of river discharge. Specifically, in northern latitudes like the Pacific Northwest, increases in flashy, event-driven runoff and decreases in spring snowmelt are projected to substantially alter seasonal hydrologic regimes^24,25. The integration of landscape-level features, such as watershed slope or past land use histories, within these larger patterns will likely produce different ecosystem responses, making local variations of river NO₃^– exports difficult to predict^23,26,27. The interaction of complex landscapes with altered climate patterns and river flows thus represents a key uncertainty in our understanding of riverine responses to ongoing climate and land use change.

While the impact of large-scale stressors may manifest differently in rivers and streams, precipitation and river flow have been shown to synchronize seasonal patterns of river NO₃^– concentration and yield across watersheds that share similar characteristics^28,29. Flow-dependent nutrient regimes at the seasonal scale have been revealed, most recently in the Great Lakes, where monthly NO₃^– concentrations were shown to be synchronous with discharge in both agricultural and unmanaged catchments²⁸. Urban streams instead exhibited high concentrations during summer low-flow periods, creating out-of-phase nutrient regimes. In mountainous landscapes, research has shown that the physical features of watersheds can act as master controls of physiochemical^23,26,30,31 and biological processes³², and constrain the susceptibility of ecosystem responses to climate and hydrologic variation. Such relationships highlight the importance of hydrologic connections and the role of both regional and local scale drivers (e.g., climate, land use, and geomorphology) in the N export dynamic, and support the notion that by evaluating temporal patterns across rivers subject to different controls, we can better understand the underlying processes that generate patterns over space and time^20,22,33.

Increasingly applied over the past decades, the stable isotopes of NO₃^– (δ¹⁵N and δ¹⁸O) are tracers of N sources and biogeochemical transformations, with potential to unravel larger spatiotemporal trends³⁴. Traditional applications of dual isotopic studies have focused on source identification using δ¹⁵N and δ¹⁸O biplots, however overlapping ranges of δ¹⁵N and δ¹⁸O of NO₃^– source values often limit direct source apportionment^14,15,35. This overlap is further confounded by soil, aquifer, and stream processes (nitrification, denitrification, and assimilation) that fractionate δ¹⁵N and δ¹⁸O of NO₃^– values and alter isotopic signatures of NO₃^– pools^34,35,36. Despite uncertainties in the assessment of sources, there is growing isotopic evidence that river NO₃^– concentrations are driven by hydrologic connections with different ecosystem compartments (e.g., direct water transfer through soils during storms events, groundwater inputs, or hyporheic exchange)^{35,37,38,39,40}. This has been shown in both temperate and tropical watersheds, where, at high river stages, NO₃^– concentrations have been isotopically linked to the transfer of soil N from the legacy of human activity or from forest organic matter^{35,37,38,39,40,41}. Inputs from atmospheric NO₃^– are also linked to the hydrograph and have been shown to increase with spring and summer snowmelt in watersheds with higher elevation areas^14,42. This suggests that instream δ¹⁵N-NO₃^– and δ¹⁸O-NO₃^– values more accurately represent a mixture of seasonally dependent N-sources and fractionations, the proportions of which largely depend on the land use history, geomorphology, and hydrographic stage of the catchment.

Whether seasonal NO₃^– dynamics are spatially coherent among rivers can help reveal the drivers of N sources and exports; however, the evaluation of seasonal patterns across river δ¹⁵N and δ¹⁸O of NO₃^– time series has yet to be explored as an isotopic tool. Here, we took advantage of a unique two-year monthly data set of NO₃^– concentration and yield, combined with corresponding sample analysis of dual-isotopes of NO₃^– (δ¹⁵N, and δ¹⁸O) from 13 rivers that drain the Puget Sound basin in Washington State (see Fig. 1 for sample sites, see Fig. 2 for measured values). We applied a series of multivariate autoregressive state space models to quantify the degree to which monthly patterns of NO₃^– yield, NO₃^– concentration, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^– (and therefore the inferred source of NO₃^–) were coherent across the basin. Through the inclusion of environmental covariates, we then characterized potential hydroclimate drivers shaping the timing, direction, and magnitude of monthly river NO₃^– dynamics, and quantified how their effects varied across systems. We aim to address three questions: (1) Are there shared monthly patterns in river NO₃^– yield, NO₃^– concentration, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^– across Puget Sound rivers, and, if so, at what spatial or functional scale? (e.g., entire Puget Sound basin, among mountain ranges, or among land use or geomorphic groupings, Table 1), (2) What climate and hydrologic variables are best related to monthly variation in river NO₃^– yield, NO₃^– concentration, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^–?, and (3) How does the response of river NO₃^– yield, NO₃^– concentration, δ¹⁵N-NO₃^– and δ¹⁸O-NO₃^– to hydro-climate variables vary with watershed-specific characteristics? By summarizing monthly variation at this regional scale, we sought to gain a better understanding of whether regional controls (like climate or hydrology), or individual watershed variation (land-use or geomorphic traits) played a larger role in driving seasonal patterns of yield, concentration, and source of river NO₃^–. Further, by looking at the individual river responses to hydroclimate variation, we sought to understand how the sensitivity of seasonal NO₃^– dynamics to hydroclimatic change might be modified by watershed-specific features, such as land use cover, soil characteristics, or watershed slope.

Fig. 1: Map and characteristics of the Puget Sound Basin watersheds of study.

a The watersheds of study shaded with their local slope in degrees. Black points represent the river water quality sampling stations. Italicized abbreviations refer to the river names, which are provided in full in Table 2. b Location of the Puget Sound Basin within Washington state and British Columbia. c Ordination plot showing principal component analysis (PCA) of watershed characteristics from the Puget Sound Basin rivers. Green points represent rivers located in the Cascade Mountains. Purple points represent rivers located in the Olympic Mountains. Length and direction of arrows on the ordination are proportional to vector loading of watershed characteristics into each principal component (PC).

Fig. 2: NO₃^– concentrations, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^– measured in the Puget Sound rivers.

a δ¹⁵N-NO₃^– plotted versus NO₃^– concentrations. b δ¹⁸O-NO₃^– plotted versus δ¹⁵N-NO₃^–. Green points are values measured in the Cascade Range rivers. Purple points are values measured in the Olympic Mountain rivers. Symbol size corresponds to the amount of precipitation (mm) that fell during the month when sample was taken. Typical ranges of the different nitrate end-members are also presented¹⁵, as well as the two typical trends (1:1 and 2:1) observed in literature¹⁵ for denitrification.

Table 1 Description model structures considered in the MARSS time series models.

Results

Shared monthly patterns in river NO₃ ^- dynamics

We found that temporal patterns in monthly river NO₃^– dynamics were strongly coherent across the Puget Sound basin at the mountain range scale. For all four response variables (NO₃^– yield, NO₃^– concentration, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^–), the model with states defined by mountain range resulted in the greatest support compared to either individual watershed, or land use, geomorphology, and basin-wide grouping structures (Supplementary Tables 1–4). The next best model in terms of river grouping was the geomorphology grouping structure, which was also consistent across all four response variables. However, none of the geomorphology models had particularly high statistical support (ΔAICc < 2), with ΔAICcs of 8.7, 3.2, 8.3, and 9.3 for NO₃^– yield, NO₃^– concentration, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^–, respectively. This suggests that monthly variation in NO₃^– yield, NO₃^– concentration, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^– was best defined by two river state processes, one for rivers located in the Cascade Range, and one for rivers located in the Olympic Mountains (Fig. 3).

Fig. 3: Modeled states for each response variable at the “Mountain range” scale (our most supported model).

Green lines are the Cascade-level modeled state for each response variable (a–d). Purple lines are the Olympic-level modeled state for each response variable (e–h). Estimates are shown with their standard error, shaded in green and purple respectively. Gray circles represent the measured water quality sample data for the individual watersheds. Blue lines represent mean daily discharge across each mountain range river group. All data are standardized by mean and variance.

Models with correlated process errors were best supported by all response variable data (Supplementary Tables 1–4). For NO₃^– yield, NO₃^– concentration, and δ¹⁸O-NO₃^–, the best process error structure had equal variance and covariance among the two state processes (Supplementary Tables 1, 2, and 4), indicating that states across the two mountain ranges were temporally correlated and shared similar magnitudes in the peaks and troughs of their curves through time. For δ¹⁵N-NO₃^–, the best model included an unconstrained Q matrix structure (Supplementary Table 3), indicating that states were temporally correlated across mountain ranges, but the magnitude of monthly variation differed between the Cascade Range and Olympic Mountain rivers.

Hydroclimate drivers of monthly river NO₃ ⁻ variation

For all response variables, the best covariate model included a shared coefficient among rivers within each mountain range (Supplementary Tables 5–8). That is, rivers in the Cascade Range shared similar effects of hydroclimate variables, while the effects of hydroclimate variables shared by rivers in the Olympic Mountains were distinctly different. For example, for both NO₃^– yield and concentration, the model including precipitation had the most data support (Supplementary Tables 5–6), but the magnitude and directionality of the precipitation effect varied for rivers in each mountain range. In the Cascade Range rivers, precipitation had a positive effect on NO₃^– concentration and yield (Fig. 4a, b), indicating that during periods of heavy rainfall, the amount and export of river NO₃^– increased. In the Olympic Mountain rivers, however, precipitation’s effect on NO₃^– yield was smaller than rivers in the Cascade Range, and the effect on river NO₃^– concentrations was strongly negative (though not statistically significant from 0, Fig. 4a, b). For both NO₃^– concentration and yield, the next best covariate model included an effect of water temperature at the mountain range scale (NO₃^– concentration ΔAIC_c = 1.9, NO₃^– yield ΔAIC_c = 9.8). In the Cascade Range rivers, water temperature had a negative effect on NO₃^– yield but was unrelated to NO₃^– concentrations. Conversely, in the Olympic Mountain rivers, the effect of water temperature was unrelated to NO₃^– yields but exhibited a strong positive effect on NO₃^– concentrations (Fig. 4a, b).

Fig. 4: Estimated MARSS model coefficients for each covariate model considered at the mountain range scale.

a Effects of water temperature, precipitation, snowmelt and Standardized Precipitation Index (SPI) on NO₃^– yield at the mountain range scale. b–d Effects of water temperature, precipitation, snowmelt, event-driven discharge (\({Q}_{{quick}}\)), seasonal discharge (\({Q}_{{slow}}\)), and SPI on NO₃^– concentration, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^– at the mountain range scale. Green points are the covariate effects shared among Cascade Range rivers. Purple points are the covariate effects shared among Olympic Mountain rivers. Points are maximum likelihood estimates for each coefficient with horizontal bars indicating the 95% confidence intervals around that estimate.

Event-scale discharge and precipitation best explained variation across δ¹⁵N-NO₃^– patterns (\({Q}_{{quick}}\) ΔAIC_c = 0, Precipitation ΔAIC_c = 6.7, Supplementary Table 7). In the Cascade Range rivers, \({Q}_{{quick}}\) had a strong, negative effect on the δ¹⁵N-NO₃^– time series (Fig. 4c), indicating that depleted δ¹⁵N-NO₃^– values were highly correlated with winter runoff or storm events. The effect of \({Q}_{{quick}}\) on δ¹⁵N-NO₃^– was, however, not present in the Olympic Mountain rivers, as indicated by an effect size that was not statistically distinguishable from 0 (Fig. 4c). Precipitation was the second-best explanatory covariate for δ¹⁵N-NO₃^– and further enforced these differences between the two mountain ranges. In the Cascade Range rivers, δ¹⁵N-NO₃^– values decreased when precipitation increased (Fig. 4c), and again, in the Olympic Mountain rivers the effect of precipitation on δ¹⁵N-NO₃^– was not statistically distinguishable from 0 (Fig. 4c).

For δ¹⁸O-NO₃^–, snowmelt was the best descriptor of isotopic variation (Supplementary Table 8). Snowmelt had a strong, positive effect on δ¹⁸O-NO₃^– in the Olympic Mountain rivers (Fig. 4d), but no effect on δ¹⁸O-NO₃^– in rivers in the Cascade Range (Fig. 4d). The second most parsimonious model for δ¹⁸O-NO₃^– at the mountain range scale included \({Q}_{{quick}}\) (ΔAICc = 7.7). Positive values of \({Q}_{{quick}}\) were strongly related to depleted δ¹⁸O-NO₃^– values in the Cascade Range (negative effect sizes, Fig. 4d). In the Olympic Mountain rivers, \({Q}_{{quick}}\) had a positive, but insignificant, effect (Fig. 4d).

For all response variables, no other explanatory covariate had a high (ΔAIC_c < 2) or moderate (ΔAIC_c < 10) degree of support. However, the second most parsimonious model for all the best explanatory covariate models included a common response to hydroclimate at the geomorphic grouping scale (Supplementary Tables 5–8).

Landscape controls of river NO₃ ^– responses to hydroclimate

The sensitivity of NO₃^–, NO₃^– yield, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^– among rivers to hydroclimate drivers (i.e., covariate effect sizes) covaried strongly with mean watershed slope (Fig. 5). For both NO₃^– concentration and yield, steep watersheds were less sensitive to the positive effects of precipitation. As mean watershed slope increased, the effect of precipitation on NO₃^– yield diminished (Fig. 5a) or became negative for NO₃^– concentration (Fig. 5b). Similarly, the negative effect of \({Q}_{{quick}}\) on δ¹⁵N-NO₃^– was greater in rivers draining relatively flat watersheds with more floodplain area and the effect lessened as watershed slope increased (Fig. 5c). Rivers draining steeper watersheds had the strongest effect of snowmelt on δ¹⁸O-NO₃^–, and this effect did not exist or was negative in less-steep watersheds (Fig. 5d).

Fig. 5: Watershed-scale MARSS covariate coefficients plotted versus mean watershed slope for each of our best covariate models.

a, b Watershed-scale effects of precipitation on NO₃^– yield and NO₃^– concentration plotted versus mean watershed slope. c Watershed-scale effects of event-driven discharge (\({Q}_{{quick}}\)) on δ¹⁵N-NO₃^– plotted versus mean watershed slope. d Watershed-scale effects of snowmelt on δ¹⁸O-NO₃^– plotted versus mean watershed slope. Green points represent the covariate effect for each of the Cascade Range rivers. Purple points represent the covariate effect in the Olympic Mountain rivers. Pearson correlation coefficients are given in the lower left or upper left corner of each plot.

Discussion

Using a unique regional dataset, we show the monthly riverine NO₃^– dynamics were coherent across watersheds within individual mountain ranges, despite wide variation in land use and hydrologic regimes across watersheds in the Puget Sound Basin. Our findings demonstrate the overarching importance of regional-scale climate drivers such as precipitation on N transport in rivers, while simultaneously identifying different components of the hydrograph as an important control of monthly NO₃^– source variation in both human-influenced and in more pristine catchments. Furthermore, we found that not all rivers were equally sensitive to hydroclimate variables, and that variation in this sensitivity was largely determined by a simple geomorphic feature - mean watershed slope. These results suggest that while regional-scale climate controls seasonal NO₃^– delivery in Puget Sound rivers, watershed topography plays a distinct role in influencing landscape-level drivers of NO₃^– source and transfer, which together modify the response of riverine NO₃^– dynamics to hydroclimatic change.

Seasonal patterns at the mountain-range scale

Monthly coherence in NO₃^– dynamics at the mountain-range scale suggests that regional-scale processes have stronger controls on seasonal patterns of NO₃^– concentration, yield, and isotopic signatures than finer watershed-scale variation. Given known links between river discharge, solute concentration, and flux^19,28,29, we anticipated some degree of coherence in NO₃^– concentration and yield time series among rivers, but the exact extent of that coherence was unknown. The separation of NO₃^– yield and NO₃^– concentration patterns in the Cascade Range and Olympic Mountain rivers likely reflects the cumulative differences in landscape composition that exist between the two mountain ranges. The lower sloped watersheds of the Cascade Range have sprawling valley floors, with larger wetland and riparian areas, deeper soils, and varied degrees of agricultural activity and human development. Watersheds in the Olympic Mountains are instead spatially constrained in relief, generally high elevation, and remain mostly forested with little to no agriculture and sparse human development (Table 2 and Fig. 1c). Our results thus agree with previous work that seasonal-scale nutrient regime curves can be driven by regional-scale variation, such as seasonal flow and precipitation patterns, but become asynchronous with varying physical traits and land use histories due to differences in source type and availability²⁸.

Table 2 River and watershed characteristics of the Puget Sound Basin rivers of study.

With large variation in watershed land use and hydrogeomorphic characteristics among the Puget Sound basin rivers (Table 2 and Fig. 1c), we expected watershed-specific traits to drive varied source proportions and processing rates and to diminish the coherence in monthly values of δ¹⁵N and δ¹⁸O of NO₃^–. Instead, despite broad variation in watershed characteristics, rivers in the Cascade Range experienced notable coherence δ¹⁵N-NO₃^– and δ¹⁸O-NO₃^– over time, and rivers in the Olympic Mountains shared strong monthly patterns of δ¹⁸O-NO₃^–, but little change in δ¹⁵N-NO₃^– (Fig. 3). The observed degree of coherence found across δ¹⁵N and δ¹⁸O of NO₃^– time series, along with the divergent patterns between the Cascade Range and Olympic Mountain rivers, suggests that the two isotopic states depict a region-specific mixture of seasonally dependent NO₃^– sources, or perhaps show cumulative fractionation processes that are similar in each river group.

Hydroclimate drivers in the Cascade Range and Olympic Mountain rivers

The support for seasonal coherence at the mountain range scale was further corroborated by our covariate analysis, where correlations between hydroclimate drivers and NO₃^– response variables highlighted fundamental differences in NO₃^– source availability, transport potential, and transformation processes across the Cascade Range and Olympic Mountains. In the Cascade Range rivers, we found that precipitation had positive effects on both NO₃^– concentration and yield, and that NO₃^– yields decreased seasonally as the hydrograph fell and river waters warmed (as indicated by the negative effect of water temperature; Fig. 4a). This finding supports the notion that in these moderately to highly disturbed catchments, river nutrient export is “transport limited”, and that NO₃^– yields are primarily driven by the seasonal mobilization of NO₃^– sources with increased precipitation and resultant river flow^19,29. In anthropogenically modified watersheds, N accumulates within soils and groundwater from fertilizer and manure applications^16,29, septic waste^43,44, N-fixing species (such as legumes or alder^18,45), or from altered atmospheric deposition patterns across the watershed^14,42,46. Consistent relationships between hydroclimate variables and NO₃^– loads across human-modified catchments have thus been attributed to the mobilization of accumulated NO₃^– pools in soils and groundwater^16,29, rather than direct runoff from surface point sources.

In the Olympic Mountain rivers, the effect of precipitation on NO₃^– yield was positive, but smaller than in the Cascade Range rivers, signaling a reduced response of monthly NO₃^– transport to increased precipitation in rivers draining relatively intact watersheds. Snowmelt had a negative effect on NO₃^– yields in Olympic Mountain rivers, which reflects a decrease in NO₃^– export during spring freshets in rivers with snow-driven hydrologies. This, combined with the uniformly negative effects of hydroclimate variables on NO₃^– concentrations, suggests that Olympic Mountain rivers were highly sensitive to the effects of seasonal dilution with increased river volume. Negative concentration-discharge relationships have been shown in other forested and undeveloped watersheds^47,48, and have been described as “source limited” due to the absence of excess watershed N supplies. In these systems, NO₃^– concentrations peak in the summer and during the rising limb of the hydrograph from increased stream or nearby soil nitrification pools, then decrease with the exhaustion of sources⁴⁷. The increase in NO₃^– concentrations with warm summer flows supports this hypothesis (positive effect of water temperature; Fig. 4b). Collectively, this indicates that the Olympic Mountain rivers are “source limited” in their NO₃^– patterns and that NO₃^– source pools are quickly depleted with the onset of fall precipitation.

Our isotopic results reinforce this distinction between “transport” and “source limited” NO₃^– regimes in the Cascade Range and Olympic Mountain rivers and highlight the importance of hydrologic connections between different ecosystem compartments, such as soil N pools. After the addition from fertilizers, atmospheric deposition, snowmelt, or mineralization within soils, NH₄ can be nitrified to NO₃^–, resulting in high NO₃^– concentrations with relatively low δ¹⁵N-NO₃^– and δ¹⁸O-NO₃^– values^{15,35,36,37,49}. This is especially relevant in watersheds with historical and current land use change, where additions of N to the landscape enhance soil mineralization and subsequent nitrification rates⁵⁰. Higher net nitrification has also been shown to occur under N-fixing red alder trees^51,52, a species prevalent along the Cascade Range valley floors due to both human and riparian disturbance. In the Cascade Range rivers, the observed negative relationship between storm event-scale variations in river flow (\({Q}_{{quick}}\)) and precipitation and δ¹⁵N-NO₃^– thus implies that heavy winter rains and flooding may uniformly and rapidly mobilize nitrified soil NH₄⁺, decreasing river δ¹⁵N-NO₃^– during high flow events. The decrease in river δ¹⁵N-NO₃^– with winter rains could also be attributed to the delivery of atmospheric NO₃^– or direct runoff from NO₃-based fertilizers. However, if that were the case, δ¹⁸O-NO₃^– would have increased with precipitation. Instead, Cascade Range δ¹⁸O-NO₃^– values decreased with increased event-scale flow and precipitation (negative effect sizes; Fig. 4), supporting a link between wintertime NO₃^– yields and inputs of nitrified soil NH₄⁺ from the legacy of human activity in the region.

The Cascade Range rivers experienced noticeable enrichment of δ¹⁵N-NO₃^– during the spring and summer months as NO₃^– exports fell (Fig. 3c). While we lack a covariate that adequately captures this seasonal variation, this could be explained by the drainage from a relatively ¹⁵N enriched NO₃^– pool, such as septic and manure waste, or by NO₃^– that has undergone denitrification or biological uptake (assimilation). During denitrification and assimilation, the lighter isotopes of δ¹⁵N and δ¹⁸O are preferentially processed, resulting in the dual isotopic enrichment of residual NO₃^{–15,35,53,54}. In fact, we do see a shared seasonal enrichment of the δ¹⁵N-NO₃^– and δ¹⁸O-NO₃^– states in Cascade Range rivers (Fig. 3c, d), suggesting that summertime NO₃^– concentrations could be influenced by nutrient retention processes that occur instream or elsewhere within watersheds. Notably, the Cascade Range watersheds have increased riparian and wetland areas, which promote anoxia and denitrification⁵⁵ (Table 2), and the river channels themselves are conducive to groundwater springs and exchange with the reactive hyporheic zone^56,57. As discharge volumes and velocities decline, it is possible that increased connections with biogeochemically reactive sites or increased proportions of denitrified NO₃^– from external pools could seasonally enrich the Cascade Range δ¹⁵N-NO₃^– and δ¹⁸O-NO₃^– river values^35,58,59. However, summertime values of δ¹⁸O-NO₃^– across the Cascade Range rivers were distinctly more variable (Fig. 3d) and could also be enriched by unprocessed atmospheric NO₃^–14,60. Furthermore, processes such as respiration and O-isotopic exchange between NO₂ and H₂O molecules during nitrification can significantly alter δ¹⁸O-NO₃^– values³⁶, making nutrient retention patterns difficult to surmise at this regional scale.

In the Olympic Mountain rivers, the observed effects of hydroclimate variables on the isotopic states suggest that NO₃^– concentrations were derived mostly from a combination of soil or instream nitrification processes and contributions from atmospheric deposition. Average δ¹⁵N-NO₃^– values were low (Fig. 2), and correlations with seasonal hydroclimate variables were insignificant (Fig. 4c). The lack of significance of δ¹⁵N-NO₃^– with temporal variables in Olympic Mountain rivers indicates that δ¹⁵N-NO₃^– values were relatively unchanged through time, and there was limited mixing among isotopically distinct sources, or isotopic enrichment from human waste or agricultural inputs. Increased snowmelt in the Olympic Mountains had a positive effect on δ¹⁸O-NO₃^–, and the singular peak of δ¹⁸O-NO₃^– in Olympic Mountain rivers coincided with local climate conditions, rising during a normal hydrologic year in 2016, but absent during 2015, which was a record drought in terms of snowpack for Washington State⁶¹. The positive effect of snowmelt, and the timing of increased δ¹⁸O-NO₃^–, implies that spring and early summer snowmelt washes unprocessed atmospheric NO₃^– downstream, increasing measurable atmospheric contributions to the Olympic Mountain river NO₃^– pools.

Landform influence on river responses to hydroclimate

The final piece of our analyses identifies watershed-scale differences in landform as a strong underlying control of the contrasting responses of the Cascade Range and Olympic Mountain rivers to hydroclimatic change. We found that a significant amount of the variation in the individual river NO₃^– responses to hydroclimate variables was explained by a simple geomorphic metric, mean watershed slope (Fig. 5). NO₃^– yields, NO₃^– concentrations, and δ¹⁵N-NO₃^– values in rivers draining flatter watersheds were distinctly more sensitive to changes in precipitation and storm-event scale flows. In contrast, δ¹⁸O-NO₃^– in rivers draining mid- to high-sloped watersheds were less sensitive to runoff-related hydrologic conditions, and highly sensitive to changes in snowmelt (Fig. 5). This relationship between river NO₃^– sensitivities and watershed slope illuminates the broad-scale influence of topography on river ecosystem function. Watershed topography can directly influence the source, transfer, and transport of NO₃^– directly through both physical and chemical mechanisms. For example, in watersheds with steep slopes, strong energy gradients rapidly route water and snowmelt to stream channels, quickly transferring available NO₃^–10,11,12. Lower relief areas instead increase residence times and rates of N reactivity^9,11,12, and also promote river connections to N sources and sinks across high flow (i.e., floodplain soils^13,62) and low flow conditions (i.e., hyporheic and channel storage zones^35,40,58). Terrain relief can also indirectly affect NO₃^– dynamics through its control on the distribution of human activity. In flat watersheds, humans populate and modify the landscape to larger degrees, enhancing the accumulation of NO₃^– on land and in soils^16,29, while often altering hydrologic flow paths⁶³. Together, this can saturate or bypass biogeochemical retention opportunities, and ultimately increase the potential for NO₃^– transfers and transport downstream^17,64.

Our results highlight that while regional-scale variation exhibits large controls on monthly NO₃^– sources and exports across the Puget Sound Basin, watershed characteristics still influence river sensitivity to hydroclimate variables. Specifically, our results imply that differences in landform, and therefore availability, source, and transfer of NO₃^–, alters NO₃^– inputs across rivers in the two mountain ranges, as well as the sensitivity of river NO₃^– transport to hydroclimatic change. This finding is similar to recent work from Alaskan watersheds^{11,12,23,26,30,31} and is meaningful in that it supports the notion that watershed slope can act as a master variable for predicting biogeochemical processes, ultimately modifying the response of river ecosystem function to climate. In the Pacific Northwest, climate change is predicted to increase the proportion of precipitation falling as rain relative to snow^61,65. With more precipitation falling as rain, instances of flooding and storm-event scale flow are likely to increase, particularly in low and mid-sloped watersheds. The results of our analyses imply that the sensitivity of river NO₃^– transport to hydro-climatic changes may be strongest in watersheds with lower slopes where excess NO₃^– can be stored and remobilized in response to precipitation and high river flows. While further research is needed to understand climate-driven perturbations to river nutrient dynamics across human modified catchments, this work demonstrates the strong influence of topography on river NO₃^– dynamics and reveals watershed slope as a potential predictor of river responses to hydroclimatic change.

Conclusions

This work contributes to the understanding of spatiotemporal patterns of river NO₃^– source and transport, including insight into seasonal patterns, as well as the identification of physical mechanisms at finer scales. We provide evidence that regional climate exhibits strong controls on monthly isotopic composition, concentration, and yield of river NO₃^–, forming distinct source and transport-driven NO₃^– regimes across two local mountain ranges. Within these broad-scale patterns, we also show that watershed landform influences the availability and transfer of NO₃^–, ultimately controlling the sensitivity of river NO₃^– dynamics to climate. Climate change is likely to have important effects on river NO₃^– transport, with impacts that will play out differently across watersheds^6,20. The clear linkage between NO₃^– regimes, hydroclimate, and landform has broad implications for river nutrient management and suggests that topographic features, such as watershed slope, could be used to improve scenarios of NO₃^– transport at the scale of regions, which will become increasingly important as climate, hydrology, and land use continues to change.

Methods

Study area

The Puget Sound basin, located mostly in western Washington State, drains an area of approximately 13,700 km² (Fig. 1). Bounded by the Olympic Mountains to the west and the Cascade Range to the east, watersheds in the basin represent a gradient of geomorphic settings, with lowland and mountain valleys formed by continental glaciers, alpine glaciers, sediment deposition, and incision from rivers⁶⁶. Climate in the basin is seasonally variable, characterized by cool, wet winters, and warm dry summers. The average annual rainfall is 2147 mm, and the average annual air temperature is 8 °C⁶⁷. During the hydrologic years of study, about 1947 and 2478 mm of precipitation fell within 2015 and 2016, respectively, and the average air temperature was 10 °C in 2015 and 9 °C in 2016⁶⁸. For watersheds along both the Cascade and Olympic ranges, about 80% of the annual precipitation occurs from October to March^67,68. Within this setting, hydrologic regimes are governed by timing and form of precipitation and are characterized as rainfall-dominated (<600 m elevation with peak discharges in November–February) and mixed rain-and-snow hydrologies (>600 m elevation with peak discharges in February–June)^66,69. Groundwater also sustains summer discharge in some rivers, as the unconsolidated glacial sediments of Puget Sound river channels are conducive to springs and hyporheic exchange^56,57. Notably, in 2015, substantial winter warming increased the proportion of precipitation falling as rain relative to snow, leading to declines in mountain snowpack and snowmelt-driven spring and summer discharge⁶¹. Though the effects of the snow drought were felt across the entire basin, watersheds in the south Cascade Range and Olympic Mountains experienced the largest impacts to their snowmelt regimes⁶¹.

Land use histories and development in the region have resulted in a gradient of human disturbance and land cover across the basin. While the slopes of the Cascade Range and Olympic Mountains remain mostly forested, transitions to urban and agricultural land uses along with increased logging since the late 1800s have removed substantial areas of floodplain forest in the lower basin. The central Puget Sound region has seen rapid urbanization in recent years, gaining over a million people since 2000⁷⁰. The south and central valleys of the western Cascade Range are now mainly urban and rural residential land, with some pastureland and forage crops (hay and corn) located outside the urban fringe^71,72. The majority of forage and specialty crop cultivation (including cereal grains, berries, and vegetables) is located in the northeastern part of the basin in the Nooksack, Skagit and Snohomish river watersheds⁷². Forested areas along the lower Cascade Range are a mix of deciduous and coniferous forest and include large stands of the early successional N-fixing tree species, red alder (Alnus rubra)⁷³. Watersheds along the eastern Olympic Mountains remain mostly forested with coniferous trees, but with some logging, and sparse pastureland, forage cropped fields and residential development^71,72. The combination of forested, mountainous areas, agricultural valleys, and sprawling cityscapes creates a variable landscape across the Puget Sound basin, and drives a diversity of N inputs that cover the full range of NO₃⁻ sources¹⁵.

Sample and data collection

We used two years of river monthly water quality samples collected by the Washington Department of Ecology’s (DoE) River and Stream Water Quality Monitoring program from October 2014 to September 2016. The Washington DoE collects monthly water quality samples at nearly 100 river and stream stations across Washington state. For this study, we selected rivers that drain the Puget Sound Basin and range in their watershed physical and land use characteristics (Table 2, Fig. 1c). This included 13 rivers, each with 1 DoE sampling station located near the Puget Sound outlet (Fig. 1). River order (i.e., Strahler number⁷⁴) at the mouth ranged from 5 to 8, and sampling stations ranged from 4 to 300 m in elevation. We obtained subsamples of monthly water samples from each river site for NO_3¯ stable isotope analysis (δ¹⁵N and δ¹⁸O) and paired them with corresponding NO_3¯ concentration data from the Washington’s Department of Ecology’s Freshwater Information Network database⁷⁵. Details concerning the Washington Department of Ecology’s water quality sample handling protocols and analytical methods can be found in Von Prause, 2021⁷⁶.

To calculate river NO₃⁻ yields, we used the composite method within the loadflex R package⁷⁷ to calculate monthly river NO₃⁻ fluxes (estimated in kg day⁻¹), and subsequently divided monthly fluxes by watershed area for monthly estimates of river NO₃⁻ yield in kg km⁻² day⁻¹. The composite method combines regression model predictions with model residuals to bring predictions closer to actual observations, thereby reducing model biases and increasing the accuracy of total flux estimates^77,78,79. We therefore chose the composite method (in comparison to other methods, such as WRTDS or LOADEST models) as it provided the best estimate of actual river NO₃⁻ yields across our rivers and our period of study. We provide plots of the monthly NO₃⁻ yields, NO₃⁻ concentrations, and NO₃⁻ stable isotopic values (δ¹⁵N and δ¹⁸O) for each river site in Supplementary Figs. 1–4.

Stable isotope analysis of NO₃ ^-

We analyzed river water subsamples for nitrogen and oxygen isotope ratios of NO₃⁻ (¹⁵N/¹⁴N and ¹⁸O/¹⁶O) using the bacterial denitrifier method^80,81 at the University of Washington’s Δ*IsoLab. Briefly, we used denitrifying bacteria (Pseudomonas aureofaciens) to convert NO₃^– and NO₂ to N₂O. The resultant N₂O was extracted, purified, and pyrolyzed to N₂ and O₂ in a heated gold tube held at 800 °C. The isotopic ratios of each gas were then measured by a Finnigan Delta-Plus Advantage isotope ratio mass spectrometer after being separated by a gas chromatograph. We report the ratios of ¹⁵N/¹⁴N and ¹⁸O/¹⁶O of NO₃⁻ in the delta (δ) notation in per mil (‰), where δ = (R_sample/R_standard − 1) and R is the ¹⁵N/¹⁴N in N₂ normalized atmospheric air N₂ (Air) or ¹⁸O/¹⁶O normalized to Vienna Standard Mean Ocean Water (VSMOW). We calibrated δ¹⁵N and δ¹⁸O of NO₃⁻ using three international reference materials, USGS34: δ¹⁵N = −1.8‰, δ¹⁸O = −27.8‰, USGS35: δ¹⁵N = +2.7‰, δ¹⁸O = +56.8‰, and IAEA-NO3: δ¹⁵N = +4.7‰, δ¹⁸O = +25.6‰. We verified analytical accuracy using replicate measurements of USGS35 and IAEA-NO3 (for δ¹⁵N and δ¹⁸O, respectively). The uncertainty was ±0.1‰ for δ¹⁵N and ±0.5‰ for δ¹⁸O (1 SD, n = 84).

Regional climate and hydrologic covariates

We considered several climate and hydrologic predictors of river NO₃^– concentration, NO₃^– yield, δ¹⁵N-NO₃^–, and δ¹⁸O-NO₃^– time series. We chose monthly precipitation, snowmelt, water temperature, and the Standardized Precipitation Index (SPI) as metrics of climatic variability. SPI is a widely used drought index which captures how precipitation deviates from the climatological average across different timescales⁸². We used 12-month SPI, which is timescale indicative of long-term drought events⁸². To calculate precipitation and snowmelt values, we extracted gridded estimates of total daily precipitation, and snow water equivalent (SWE) data for each watershed boundary from Oak Ridge National Laboratory’s Daymet dataset⁸³ and summed the estimates per each month sampled. We then calculated monthly snowmelt for each watershed as the absolute value of negative differences in the cumulative SWE from each month to the next. We extracted monthly gridded estimates of 12-month SPI for each watershed boundary from the National Oceanic and Atmospheric Administration’s nClimGrid-monthly dataset⁸⁴. We obtained monthly water temperature measurements from the Washington’s Department of Ecology’s Freshwater Information Network database⁷⁵, which were taken in the field alongside the provided river water quality samples.

To evaluate the influence of river hydrologic variation, we included both event-driven and seasonal components of each river’s discharge hydrograph. By considering different components of the hydrograph in our analysis, we sought to reveal the role of flashy, runoff-driven flow vs. the sustained, seasonal pulse of river discharge in driving monthly river NO₃^– variation. To calculate seasonal and storm event-scale variations in discharge, we used recession analysis, a method that separates discharge hydrographs into short-term discharge variations driven by surface or interflow during storm events, and baseflow variations driven by slower water transit or eventual groundwater inputs^85,86,87. We extracted daily discharge data from the nearest U.S. Geological Survey gaging station to each study site for the 2 years of study (no greater than 30 km from the sampling point)⁸⁸. To estimate the slow, seasonal (\({Q}_{{slow}}\)), and quick, short-term (\({Q}_{{quick}}\)) components of the hydrograph, we applied the baseflow recursive filter method^85,89 to each river hydrograph. To preserve the scale of individual storm events, we kept \({Q}_{{quick}}\) as the raw daily value specific to the sample date. To incorporate the influence of river flow at the seasonal scale, we calculated \({Q}_{{slow}}\) as the previous week sum of estimated baseflow values. Further details on the estimation and chosen time windows of \({Q}_{{quick}}\) and \({Q}_{{slow}}\) can be found in the supplemental material (Supplementary Note 1 and Supplementary Fig. 5).

Watershed and landscape characteristics

We compiled watershed-scale landscape metrics for each of the watersheds corresponding to our 13 river sites using the Environmental Protection Agency’s StreamCat data library (Table 2). These metrics included watershed area, mean watershed elevation, mean watershed soil depth, mean soil organic matter, watershed population density, and percent urban, wetland, agricultural, and forested land. We also included mean watershed slope in our analyses as it captures aspects of watershed topography and stream geomorphology that may influence NO₃^– accumulations or transfers, such as water residence times, floodplain area, and hydrologic connectivity^9,10,12. We calculated watershed slope as the average of all slope raster pixels within the boundaries of each individual river’s watershed using ArcGIS (v10.8).

Time series modeling approach

We used multivariate autoregressive state space (MARSS) models to examine temporal trends in NO₃⁻ concentration, NO₃⁻ yield, and NO₃⁻ isotopic composition (δ¹⁵N and δ¹⁸O) across 13 major rivers in the Puget Sound basin⁹⁰. MARSS models are a powerful class of time series models that can be used to evaluate hypotheses regarding synchrony among multiple time series^91,92,93. MARSS models consist of two equations. The process Eq. (1) is an estimate of changes in the true, but hidden, states of nature over time. The observation Eq. (2) relates actual observations to the unobservable process Eq. (1).

$${{{{{{\bf{x}}}}}}}_{t}={{{{{\bf{B}}}}}}{{{{{{\bf{x}}}}}}}_{t-1}+{{{{{\bf{C}}}}}}{{{{{{\bf{c}}}}}}}_{t-h}+{{{{{{\bf{w}}}}}}}_{t}{{{{{\rm{;}}}}}}{{{{{{\bf{w}}}}}}}_{t} \sim {{{{{\rm{MVN}}}}}}\left({{{{{\bf{0}}}}}},{{{{{\bf{Q}}}}}}\right)$$

(1)

$${{{{{{\bf{y}}}}}}}_{t}={{{{{\bf{Z}}}}}}{{{{{{\bf{x}}}}}}}_{t}+{{{{{{\bf{v}}}}}}}_{t}{{{{{\rm{;}}}}}}{{{{{{\bf{v}}}}}}}_{t} \sim {{{{{\rm{MVN}}}}}}\left({{{{{\bf{0}}}}}},{{{{{\bf{R}}}}}}\right)$$

(2)

In the process model (1), x_t is a j x 1 vector of hidden states in month t; j changes with each structure of Z tested in the observation equation. The j x j matrix B contains estimated parameters along the diagonal that determine the degree of mean‐reversion of each state process, and zeros elsewhere. The j × k matrix C contains the model-estimated effects of environmental covariates measured at time t − h, where h represents the time lag between the covariate and the response. The c_t‐h vector (k × 1) contains each of the measured hydro-climatic covariate values. The j × 1 vector w_t contains process errors, which are distributed as a multivariate normal with mean vector 0 and covariance matrix Q. The off-diagonals of the Q matrix measure covariance in the process errors after accounting for shared trends, thus providing an estimate of independence or correlation between the modeled trends, x_t.

In the observation model (2), y_t is an i × 1 vector of measured data (log NO₃^– concentration, log NO₃^– yield, or δ¹⁵N and δ¹⁸O of NO₃^–) at time t from each watershed (i = 13). The Z matrix maps each of the measured river time series (i = 13) onto the hidden states in x_t (the term state refers to the true, but unobserved temporal pattern of NO₃^– concentration, yield, or isotopic value). The i × 1 vector v_t contains the observation errors, which are distributed as a multivariate normal with mean vector 0 and covariance matrix R.

Testing for seasonal patterns in NO₃ ⁻ dynamics

By specifying different structures of the Z matrix, we evaluated the data support for synchrony among NO₃^– concentration, NO₃^– yield, δ¹⁵N and δ¹⁸O of NO₃^– time series at different spatial and functional scales ranging from the entire Puget Sound basin to individual watersheds (Table 2). We modeled each response variable separately and tested five options for the Z matrix, which represented the following river groupings: (1) all rivers follow the same state (Basin model), (2) there are two states defined by mountain range, one for rivers located in the Cascade Range, and one for rivers located in the Olympic Mountains (Mountain model), (3) there are three states defined by watershed land use (Land use model), (4) there are three states defined by watershed topographic and soil characteristics (Geomorphology model), and (5) each river follows its own independent state or trend through time (Watershed model). To define the Land use and Geomorphology model groupings, we used k-means clustering analyses to group the Puget Sound rivers based on the similarity and closeness of their watershed land use and geomorphic characteristics (Table 1 and Supplementary Note 2). To evaluate the possible variance and covariance among state processes, we tested data support for four options of the Q matrix including: equal variance and equal covariance, independent variance and independent covariance, independent variance but no covariance, and equal variance but no covariance. Because the collection and laboratory analysis of all samples was the same, we modeled the observation errors as independent and identically distributed (IID), such that R had a single estimated value along the diagonal and zeros elsewhere. In this piece of analysis, we set both the C and c matrices to zero.

Testing covariates as drivers of monthly variation

To evaluate the data support for different climate and hydrologic drivers of temporal variation in NO₃^– concentration, NO₃^– yield, δ¹⁵N and δ¹⁸O of NO₃^–, and to test whether the effects of hydroclimate variables were shared across different spatial or functional scales, we used our “Watershed” scale model and adjusted the C matrix of the process model (1) to apply the covariate data in the c matrix to each watershed state process. We compared models that included 6 potential covariates: water temperature, precipitation, \({Q}_{{quick}}\) (as a measure of event-scale discharge), \({Q}_{{slow}}\) (as a measure of seasonal-scale baseflow), snowmelt, and SPI. To reduce the number of model parameters, we fit each model with a single covariate, but compared five coefficient or “effect” options. This included (1) a Basin effect where state processes among all rivers responded identically to hydroclimate (one C coefficient per covariate); (2) a Mountain range effect where state processes among all rivers in a given mountain range (i.e., Cascade Range vs. Olympic Mountains) responded identically to hydroclimate (C = 2); (3) a Land use effect where state processes among rivers that share similar watershed land use responded identically to hydroclimate (C = 3); (4) a Geomorphology effect where state processes among rivers that share similar watershed topography and soil characteristics responded identically to hydroclimate (C = 3), and (5) a Watershed effect where state processes for each river responded uniquely to hydroclimate (C = number of state processes (13); Table 1). To avoid double counting discharge, we did not include discharge (\({Q}_{{quick}}\) or \({Q}_{{slow}}\)) as a covariate for our NO₃^– yield models.

To facilitate model comparisons and interpretation across river groupings and covariates, we standardized all response variable and covariate data to have a mean of 0 and standard deviation of 1. In our test for spatial synchrony, we used Akaike Information Criterion adjusted for small sample size (AICc)⁹⁴ to rank models with varying numbers of states as determined by the Z matrix and different forms of Q. In our covariate analysis, we again used AICc to rank different models that varied by which covariate was included (c matrix) and the extent to which the effect of the coefficient was shared or unique (C matrix). We also included a null “Watershed” model with no covariates. For both analyses, we selected the model with the lowest AICc value as the best model. We considered models with a ∆AICc of less than 10 to show moderate statistical support.

Post hoc, we used Pearson correlation coefficients to examine if variation in river-specific covariate effect sizes (C) could be explained by watershed geomorphic or land use attributes (including watershed area, elevation, slope, soil depth, soil organic matter, and percent urban, wetland, agricultural, and forested land).