Prolonged exposure to elevated indoor formaldehyde levels poses significant health risk. This study investigates the emission characteristics of building materials, indoor environmental parameters, and their impacts on Chinese residents. Eleven representative cities across five climate zones in China were analyzed to predict indoor formaldehyde concentrations, assess population exposure doses, and evaluate cancer risks for three grades of building materials (E, E, and E). Results indicate that the average indoor formaldehyde concentrations ranged from 0.008 to 0.028 mg/m for E, 0.014-0.057 mg/m for E, and 0.027-0.109 mg/m for E. Formaldehyde pollution was more severe in summer than winter and higher in bedrooms than in living rooms. Due to heating policies, indoor formaldehyde concentrations in severe cold (Zone I) and cold zones (Zone II) during winter were significantly higher than those in other climate zones, with a maximum difference of 2.34 times. The lifetime cancer risk for populations exposed to E grade building materials ranged from 3.0 × 10 to 8.6 × 10, exceeding acceptable risk thresholds. Infants exhibited daily exposure dose over 2.8 times higher than adults. Replacing E grade materials with E grade materials across various climate zones could reduce cancer risk by 62.2-78.2 %. Adopting higher-grade building materials is a feasible and effective strategy for mitigating health risks associated with indoor formaldehyde exposure.
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