Effects of Topographic Resolution and Geologic Setting on Spatial Statistical River Temperature Models

O’Sullivan, Antóin M.; Devito, K. J.; Ogilvie, Jae; Linnansaari, Tommi; Pronk, Toon; Allard, Serge; Curry, R. Allen

doi:10.1029/2020wr028122

Cited by 28 publications

(36 citation statements)

References 113 publications

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“…In the Miramichi, the majority of wetlands are located in upland areas. It is likely that these upland wetlands are tightly coupled with climatic and solar radiative forcing, thereby providing heat to the rivers that flow through them in summer (e.g., Monk et al 2013, O'Sullivan et al 2020a. Precipitation was negatively correlated with temperature in all MLR and SSN models and was the least important parameter in the RF models (Tables 4 and 5).…”

Section: River Temperature Model Performancementioning

confidence: 99%

“…Landscape structure and form are highly influential on the spatial variability of river temperatures within the Miramichi catchment (Monk et al 2013, O'Sullivan et al 2019a. In particular, elevation and valley wall slope are suggested to have a significant role in river temperature regimes in the catchment (O'Sullivan et al 2020a). Elevation was calculated as average elevation delimited by the catchment area upriver of a sampling location.…”

Section: Landscape Predictorsmentioning

confidence: 99%

“…It is becoming increasingly apparent that surface water-groundwater interactions can significantly modify river thermal regimes (e.g., Constantz 1998, Briggs et al 2017. O'Sullivan et al (2020a) demonstrated that bedrock hydraulic conductance influenced river temperature in the Miramichi, hypothesizing that both bedrock geology and topography influence how groundwater impacts river temperature. Haitjema and Mitchell-Bruker (2005) introduced the concept of a water table ratio (WTR).…”

Section: Landscape Predictorsmentioning

confidence: 99%

“…The advent of spatial statistical models for river networks has allowed for unprecedented insights into the spatial variability of river thermal regimes at regional scales (e.g., Turschwell et al 2016, Isaak et al 2017, Jackson et al 2017). However, recent work has suggested that while current spatial statistical models can account for spatial autocorrelation of surface water dominant river networks, they are less effective in regions where surface water has strong connections to groundwater, particularly water with weak links to surface conditions, for example, bedrockderived or deep-sourced groundwater (Tague et al 2007, O'Sullivan et al 2020a). We found that a RF approach generated more accurate river temperature models.…”

Section: River Temperature Model Performancementioning

confidence: 99%

“…Valley incision has been shown to be influential to river thermal regimes (see Dugdale et al 2015, Briggs et al 2020). However, this influence is suggested to be governed by hydraulic conductance of the underlying geologic material, where incisions in areas with low hydraulic conductance geomaterial can lack significant groundwater influence and are more influenced by climatic and solar radiative forcing (e.g., O'Sullivan et al 2020a). The negative correlation between valley wall slope and WTR and the increased importance in both parameters during maximum temperature events may therefore be linked to surface water-groundwater interactions.…”

Section: River Temperature Model Performancementioning

confidence: 99%

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Salmonid thermal habitat contraction in a hydrogeologically complex setting

et al. 2021

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Broadening our understanding of river thermal variability is of paramount importance considering the role temperature plays in aquatic ecosystem health. At the catchment scale, spatial statistical river network models (SSN) are popular for analyses of river temperature, as these are less “data hungry” than other modeling methods, and have offered invaluable insights into how thermal habitats of salmonids may change with climate warming. However, recent work has demonstrated that hydrogeological complexity can disrupt river temperature spatial autocorrelation. We test the prediction that the non‐linearity of hydrological processes inherent in a hydrogeologically complex setting, such as the Miramichi River, invalidates the SSN approach, and a Random Forest (RF) model can overcome these complexities. In all instances, RFs outperformed SSNs when predicting average (TwA) and maximum (TwM) August river temperature during 2017, and were quite robust (TwA and TwM: R2 = 0.93; RMSE = 0.6°C; R2 = 0.91; RMSE = 1.0°C, respectively). We conclude that RF models can capture the inherent non‐linearity of hydrological processes in complex hydrogeologic settings. We examined thermal habitat change for adult and 1+/2+ Atlantic salmon—AS—(Salmo salar), and all age classes of brook trout—BKT—(Salvelinus fontinalis), during August 2017, with thresholds of behavioral thermoregulation specific to the catchment. We assumed a baseline = TwA and investigated river network contraction (km) for TwM. During TwA, all habitat was suggested to be thermally suitable for 1+/2+ AS (<23°C), but 4.2% was unsuitable for adult AS and BKT of all ages (>20°C). For TwM, ~80% of the catchment was predicted to be unsuitable for adult AS and BKT. We examined two boundaries for behavorial thermoregulation in 1+/2+ AS: >23°C and >27°C. For the >23°C boundary, ~27.7% of the catchment is thermally unsuitable during TwM, and 4.9% is thermally unsuitable for the >27°C boundary. TwA in August 2017 was identical to long‐term (1970–1999) July–August TwA, as such these thermal maps will be useful for resource managers.

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Section: River Temperature Model Performancementioning

confidence: 99%

Section: Landscape Predictorsmentioning

confidence: 99%

Section: Landscape Predictorsmentioning

confidence: 99%

Section: River Temperature Model Performancementioning

confidence: 99%

Section: River Temperature Model Performancementioning

confidence: 99%

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Salmonid thermal habitat contraction in a hydrogeologically complex setting

et al. 2021

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Disentangling effects of habitat on salmonid abundance in thermal refuges while accounting for imperfect detection

Sullivan,

Vokoun

2023

Ecosphere

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Thermal refuges provide critical habitat for cold‐water‐dependent salmonids in marginal riverscapes during extreme heat events globally. Studies of thermal refuge use by salmonids are complicated by short‐term changes in weather conditions during heat waves, intermittent fish use, and the use of different analytical endpoints. We passively surveyed cold‐water‐dependent brown, rainbow, and brook trout (hereafter “trout”) thermoregulating in several thermal refuges along the Housatonic River, Connecticut, USA, during a two‐week heatwave using underwater action cameras (UACs). Using these data, we assessed the influence of various short‐term riverscape conditions on the abundance of trout within thermal refuges using a zero‐inflated Poisson, time‐stratified N‐mixture model in a Bayesian framework that accounts for imperfect detection. We detected at least one trout per sampling occasion, and estimated abundances summed across all thermal refuges ranged from 63.99 (95% credible interval [CRI] = 55.0–79.0) to 182.04 (167.0–199.0). We estimated higher trout abundances in larger thermal refuges located in low‐gradient river sections, and refuges that were deeper and cooler than the Housatonic River during the sampling occasion (all β estimates >0.0 and did not overlap zero). We also found evidence that less variable and cooler temperature regimes in the nearby Housatonic River led to higher estimated trout abundances within thermal refuges (all β estimates <0.0 and did not overlap zero). Last, we found that trout detection probabilities within thermal refuges were moderate (range = 0.521–0.634) when using UAC surveys and that the video image brightness negatively influenced detection (αbright = −0.193, 95% CRI = −0.330 to −0.058). To aid in trout population persistence in dynamic, marginal riverscapes as the climate changes, focusing on modifiable refuge attributes (e.g., depth, cold‐water plume area), and strategically targeting refuges in riverscape segments beneficial to trout may be tactics that could enhance conservation strategies globally.

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Deep learning approaches for improving prediction of daily stream temperature in data‐scarce, unmonitored, and dammed basins

Rahmani

Oliver

Lawson

et al. 2021

Hydrological Processes

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Basin‐centric long short‐term memory (LSTM) network models have recently been shown to be an exceptionally powerful tool for stream temperature (Ts) temporal prediction (training in one period and predicting in another period at the same sites). However, spatial extrapolation is a well‐known challenge to modelling Ts and it is uncertain how an LSTM‐based daily Ts model will perform in unmonitored or dammed basins. Here we compiled a new benchmark dataset consisting of >400 basins across the contiguous United States in different data availability groups (DAG, meaning the daily sampling frequency) with and without major dams, and studied how to assemble suitable training datasets for predictions in basins with or without temperature monitoring. For prediction in unmonitored basins (PUB), LSTM produced a root‐mean‐square error (RMSE) of 1.129°C and an R2 of 0.983. While these metrics declined from LSTM's temporal prediction performance, they far surpassed traditional models' PUB values, and were competitive with traditional models' temporal prediction on calibrated sites. Even for unmonitored basins with major reservoirs, we obtained a median RMSE of 1.202°C and an R2 of 0.984. For temporal prediction, the most suitable training set was the matching DAG that the basin could be grouped into (for example, the 60% DAG was most suitable for a basin with 61% data availability). However, for PUB, a training dataset including all basins with data was consistently preferred. An input‐selection ensemble moderately mitigated attribute overfitting. Our results indicate there are influential latent processes not sufficiently described by the inputs (e.g., geology, wetland covers), but temporal fluctuations can still be predicted well, and LSTM appears to be a highly accurate Ts modelling tool even for spatial extrapolation.

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Effects of Topographic Resolution and Geologic Setting on Spatial Statistical River Temperature Models

Cited by 28 publications

References 113 publications

Salmonid thermal habitat contraction in a hydrogeologically complex setting

Salmonid thermal habitat contraction in a hydrogeologically complex setting

Disentangling effects of habitat on salmonid abundance in thermal refuges while accounting for imperfect detection

Deep learning approaches for improving prediction of daily stream temperature in data‐scarce, unmonitored, and dammed basins

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