Abstract
River water quality monitoring at limited temporal resolution can lead to imprecise and inaccurate classification of physicochemical status due to sampling error. Bayesian inference allows for the quantification of this uncertainty, which can assist decision-making. However, implicit assumptions of Bayesian methods can cause further uncertainty in the uncertainty quantification, so-called second-order uncertainty. In this study, and for the first time, we rigorously assessed this second-order uncertainty for inference of common water quality statistics (mean and 95th percentile) based on sub-sampling high-frequency (hourly) total reactive phosphorus (TRP) concentration data from three watersheds. The statistics were inferred with the low-resolution sub-samples using the Bayesian lognormal distribution and bootstrap, frequentist t test, and face-value approach and were compared with those of the high-frequency data as benchmarks. The t test exhibited a high risk of bias in estimating the water quality statistics of interest and corresponding physicochemical status (up to 99% of sub-samples). The Bayesian lognormal model provided a good fit to the high-frequency TRP concentration data and the least biased classification of physicochemical status (< 5% of sub-samples). Our results suggest wide applicability of Bayesian inference for water quality status classification, a new approach for regulatory practice that provides uncertainty information about water quality monitoring and regulatory classification with reduced bias compared to frequentist approaches. Furthermore, the study elucidates sizeable second-order uncertainty due to the choice of statistical model, which could be quantified based on the high-frequency data.
Highlights
Global water quality has deteriorated in recent decades due to increased pollution from different sources (Seitzinger261 Page 2 of 17 et al 2010)
The high-frequency total reactive phosphorus (TRP) concentrations at the monitoring sites showed some bimodality with the higher mode
261 Page 6 of 17 possibly representing increased TRP concentrations during storm events, when sediment is flushed from the system (Jordan et al 2005; Jordan et al 2007)
Summary
Global water quality has deteriorated in recent decades due to increased pollution from different sources (Seitzinger261 Page 2 of 17 et al 2010). Global water quality has deteriorated in recent decades due to increased pollution from different sources Nutrient run-off from point and diffuse sources into surface and ground waterbodies increased problems such as eutrophication and anoxic conditions and impeded water use (Smith 2003; Vörösmarty et al 2010). Water quality monitoring is an important tool in analysing temporal and spatial trends of water quality, identifying emerging environmental issues, planning measures to mitigate pollution, and evaluating the effectiveness of such measures (Bradley et al 2015). In the European Union (EU), the Water Framework Directive (WFD) stipulates targets of improvement of the water environment and outlines water management measures that member states should implement (EU 2000). According to the WFD, physicochemical quality of waterbodies should be monitored regularly and river basin management plans produced . The Directive only specifies a minimum frequency of monitoring, and water quality is usually monitored at limited frequency, which is typical for other parts of the world (Alexander et al 1998; EU 2009)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
