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- Title
Identifying persistent temperature inversion events in a subalpine basin using radon-222.
- Authors
Kikaj, Dafina; Vaupotič, Janja; Chambers, Scott D.
- Abstract
One year of meteorological and atmospheric radon observations in a topographically complex subalpine basin are used to identify persistent temperature inversion (PTI) events. PTI events play a key role in public health due to the accumulation of urban pollutants that they cause. Two techniques are compared: a new radon-based method (RBM), based on single-height 222Rn measurements from a single centrally located station, and an existing pseudo-vertical temperature gradient method (TGM) based on observations from eight weather stations around the subalpine basin. The RBM identified six PTI events (four in winter, two in autumn), a subset of the 17 events identified by the TGM. The RBM was more consistent in its identification of PTI events for all seasons and more selective of persistent strongly stable conditions. The comparatively poor performance of the TGM was attributed to seasonal inconsistencies in the validity of the method's key assumptions (influenced by mesoscale processes, such as local drainage flows, nocturnal jets, and intermittent turbulence influence) and a lack of snow cover in the basin for the 2016–2017 winter period. Corresponding meteorological quantities for RBM PTI events (constituting 27 % of the autumn–winter cold season) were well characterized. PTI wind speeds in the basin were consistently low over the whole diurnal cycle (typically 0.2–0.6 m s -1). Suitability of the two techniques for air quality assessment was compared using hourly PM 10 observations. Peak PM 10 concentrations for winter (autumn) PTI events were underestimated by 13 µ g m -3 (11 µ g m -3) by the TGM compared with the RBM. Only the RBM indicated that nocturnal hourly mean PM 10 values in winter PTI events can exceed 100 µ g m -3 , the upper threshold of low-level short-term PM 10 exposure according to World Health Organization guidelines. The efficacy, simplicity, and cost effectiveness of the RBM for identifying PTI events has the potential to make it a powerful tool for urban air quality management in complex terrain regions, for which it adds an additional dimension to contemporary atmospheric stability classification tools. Furthermore, the long-term consistency of the radon source function will enable the RBM to be used in the same way in future studies, enabling the relative magnitude of PTI events to be gauged, which is expected to assist with the assessment of public health risks.
- Subjects
WORLD Health Organization; TEMPERATURE inversions; SNOW accumulation; AIR quality management; HEALTH risk assessment; METEOROLOGICAL stations; ATMOSPHERIC radon; CRYOSPHERE
- Publication
Atmospheric Measurement Techniques, 2019, Vol 12, Issue 8, p4455
- ISSN
1867-1381
- Publication type
Article
- DOI
10.5194/amt-12-4455-2019