Quantifying effects of meteorological parameters on air pollution in Kathmandu valley through regression models

Most studies on air pollution have focused on source apportionment aspect but very few have considered meteorological factors responsible for variation in air pollution levels including studies in Nepal. Consequently, the effects of meteorological parameters including effects of seasonality and lag effects are investigated and quantified for Kathmandu valley, Nepal. Daily temporal data of air pollution for 2017–early 2020 monitored by the Department of Environment and US Embassy, Kathmandu, Nepal, and meteorological data monitored by the Department of Hydrology and Meteorology, Kathmandu, Nepal, are used. Regression models namely exponential, Box-Cox transformed and Gamma generalized linear models are used to quantify the effects supported by regression diagnostics. Results depict high proportions of observed air pollution variations (79–85%) explained by the fitted models with varied effects of meteorological parameters. Around 5% reduction in PM 10 (96% CI : 0.034–0.069) and PM 1 (95% CI : .0.029–0.063) levels per 1 °C increase in average temperature and significant increase in surface O 3 level (0.177, 95% CI : 0.126–0.228 Box-Cox transformed value) per 1 °C increase in average temperature are detected. Similarly, around 0.7% (95% CI : 0.1–1.3) and 2% (96% CI :1.3–2.5) decrease in PM 1 and PM 10 , respectively per 1% increase in relative humidity, 0.032 (95% CI : 0.024–0.040) decrease in transformed value of PM 2.5 per 1 mm increase in rainfall, and 7.3% (95% CI : 1.3–15.9) decrease in PM 10 per 1 m/s increase in wind speed are also detected. In conclusion, meteorological conditions are found significant contributing factors in determining air pollution levels in Kathmandu valley. On the long run, atmospheric conditions can play vital roles in air pollution situation shifts mainly due to climate change characterized by changes in meteorological values.