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Measurement and source apportionment of atmospheric pollutants are crucial for the assessment of air quality and the implementation of policies for their improvement. In most cases, such measurements use expensive regulatory-grade instruments, which makes it difficult to achieve wide spatial coverage. Low-cost sensors may provide a more affordable alternative, but their capability and reliability in separating distinct sources of particles have not been tested extensively yet. The present study examines the ability of a low-cost optical particle counter (OPC) to identify the sources of particles and conditions that affect particle concentrations at an urban background site in Birmingham, UK. To help evaluate the results, the same analysis is performed on data from a regulatory-grade instrument (SMPS, scanning mobility particle sizer) and compared to the outcomes from the OPC analysis. The analysis of the low-cost sensor data manages to separate periods and atmospheric conditions according to the level of pollution at the site. It also successfully identifies a number of sources for the observed particles, which were also identified using the regulatory-grade instruments. The low-cost sensor, due to the particle size range measured (0.35 to 40 µm), performed rather well in differentiating sources of particles with sizes greater than 1 µm, though its ability to distinguish their diurnal variation, as well as to separate sources of smaller particles, at the site was limited. The current level of source identification demonstrated makes the technique useful for background site studies, where larger particles with smaller temporal variations are of significant importance. This study highlights the current capability of low-cost sensors in source identification and differentiation using clustering approaches. Future directions towards particulate matter source apportionment using low-cost OPCs are highlighted.
|Number of pages||17|
|Journal||Atmospheric Measurement Techniques|
|Publication status||Published - 7 Jun 2021|
Bibliographical noteFunding Information:
This research has been supported by the Natural Environment Research Council (grant no. NE/T001879/1) and the Engineering and Physical Sciences Research Council (grant no. EP/T030100/1).
Financial support. This research has been supported by the Natu-
© Author(s) 2021.
- 1 Finished
Quantification of Utility of Atmospheric Network Technologies (QUANT)
NATURAL ENVIRONMENT RESEARCH COUNCIL
13/02/19 → 12/02/23
Project: Research project (funded) › Research