Direct Measurement of Aerosol Liquid Water Content: A Case Study in Summer in Nanjing, China

Overview

Journal Toxics

Date 2024 Mar 27

PMID 38535897

Authors

Daoming Li

Shijie Cui

Yun Wu

Junfeng Wang

Xinlei Ge

Affiliations

Soon will be listed here.

Abstract

Aerosol liquid water content (ALWC) affects the mass loading, optical properties, and toxicity of aerosols. However, the measurement of ALWC is very rare due to its requirement of sophisticated instruments and its high operational costs. In this work, we improved on our previous simple, low-cost method by using a combination of one real-time fine particulate matter (PM) monitor and two turbidimeters and successfully applied these for the direct measurement of ALWC in PM in Nanjing during the summer of 2023. The average ALWC during this measurement period occupied ~1/6 of the total PM mass, and this contribution was even greater with the elevation in the PM concentration. The ALWC was, as anticipated, closely related to the relative humidity (RH) and PM concentrations, but it did not always increase with the air quality index (AQI) due to the fact that polluted periods in summer were often governed by high O levels, not PM levels. The ALWC also had a great impact on visibility; it could decrease the visibility rapidly to hazy conditions when the dry PM was not high (~30 μg m) or the AQI was "good" (75~100), indicating that the air quality classified as "good" using the dry PM concentration might actually be "lightly polluted" if the ALWC is included. We also found that the air mass originating from Northeast China had the lowest PM mass concentration yet the highest ALWC values due to its high RH. Moreover, the quantification of ALWC levels can help us understand the solubility/bioavailability and thus the toxic effects of some specific components (for example, heavy metals or organics). Moreover, the influence of ALWC on air quality classifications should also be considered in the assessment of the health effects of air pollution and in public health early warning and protection.

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