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http://dx.doi.org/10.5668/JEHS.2022.48.5.272

A Study on the Spatiotemporal Characteristics of Chemical Discharges and Quantified Hazard-Based Result Scores Using Pollutant Release and Transfer Register Data  

Lim, Yu-Ra (Medical Research Center, Seoul National University)
Gan, Sun-Yeong (Division of Environmental Health, Korea Environment Institute)
Bae, Hyun-Joo (Division of Environmental Health, Korea Environment Institute)
Publication Information
Journal of Environmental Health Sciences / v.48, no.5, 2022 , pp. 272-281 More about this Journal
Abstract
Background: The constant consumption of chemical products owing to expanding industrialization has led to an increase in public interest in chemical substances. As the production and disposal processes for these chemical products cause environmental problems, regional information on the hazard level of chemical substances is required considering their effects on humans and in order to ensure environmental safety. Objectives: This study aimed to identify hazard contribution and spatiotemporal characteristics by region and chemical by calculating a hazard-based result score using pollutant release and transfer register (PRTR) data. Methods: This study calculated the chemical discharge and hazard-based result score from the Risk-Screening Environmental Indicators (RSEI) model, analyzed their spatiotemporal patterns, and identified hotspot areas where chemical discharges and high hazard-based scores were concentrated. The amount of chemical discharge and hazard-based risk scores for 250 cities and counties across South Korea were calculated using PRTR data from 2011 to 2018. Results: The chemical discharge (high densities in Incheon, Daegu, and Busan) and hazard-based result scores (high densities in Incheon, Chungcheongnam-do, and some areas of Gyeongsangnam-do Province) showed varying spatial patterns. The chemical discharge (A, B) and hazard-based result score (C, D) hotspots were identified. Additionally, identification of the hazard-based result scores revealed differences in the type of chemicals contributing to the discharge. Ethylbenzene accounted for ≥80% of the discharged chemicals in the discharge hotspots, while chromium accounted for >90% of the discharged chemicals in the hazard-based result score hotspots. Conclusions: The RSEI hazard-based result score is a quantitative indicator that considers the degree of impact on human health as a toxicity-weighted value. It can be used for the management of industries discharging chemical substances as well as local environmental health management.
Keywords
Risk-Screening Environmental Indicators; pollutant release and transfer register; hazard score;
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