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Variability and Uncertainty Analysis of N<sub>2</sub>O Emissions from WWTP to Improve the Accuracy of Emission Factors and the Design of Monitoring Strategies

Carlos Domingo‐Félez, Marlene Mark Jensen, Anders Bang, Barth F. Smets

2024ACS ES&T Water16 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide Investigations on global nitrous oxide (N 2 O) emissions from wastewater treatment plants (WWTPs) often overlook data variability and uncertainty by utilizing averaged emission factors (EF and N 2 O emitted/total nitrogen load). The variability of the EF is system-specific: technology, operation, influent characteristics, and microbial community. The uncertainty of the EF is associated with the monitoring campaign: number of measuring locations, analytical methods, data frequency, and duration. This study quantified the spatial and temporal variability of N 2 O emissions and EF from liquid measurements of N 2 O in a surface-aerated WWTP over a 110-day campaign. The gas stripping model (k L a N 2 O ) yielded a minimum measurement error of 10.4% and 13.0% for the TN load . Daily patterns of N 2 O concentrations and emissions were not normally distributed but positively skewed, suggesting that log-distributions are more accurate descriptors (11.6% of the days emitted 50% of emissions). The EF was 0.30 ± 1.29% ( n = 117602), and the higher standard deviation of the mean highlights the inaccuracy of normal distributions for N 2 O data sets, whereas the median and 2.5–97.5th quantiles and/or continuous log-distributions are more informative. An in silico analysis indicates that monitoring 5 out of 30 min instead of continuously provides reasonable accuracy and precision while allowing for six different monitoring locations.

Topics & Concepts

Environmental scienceOdor and Emission Control TechnologiesAir Quality Monitoring and ForecastingIndustrial Gas Emission Control