Details

Autor(en) / Beteiligte

• Wang, Yuxuan
• Zhang, Qianqian
• Jiang, Jingkun
• Zhou, Wei
• Wang, Buying
• He, Kebin
• Duan, Fengkui
• Zhang, Qian
• Philip, Sajeev
• Xie, Yuanyu

Titel

Enhanced sulfate formation during China's severe winter haze episode in January 2013 missing from current models

Ist Teil von

• Journal of geophysical research. Atmospheres, 2014-09, Vol.119 (17), p.10,425-10,440

Ort / Verlag

Washington: Blackwell Publishing Ltd

Erscheinungsjahr

2014

Link zum Volltext

Quelle

Wiley Online Library - AutoHoldings Journals

Beschreibungen/Notizen

• A regional haze with daily PM2.5 (fine particulate matters with diameters less than 2.5 µm) exceeding 500 µg/m3 lasted for several days in January 2013 over North China, offering an opportunity to evaluate models. Observations show that inorganic aerosols (sulfate, nitrate, and ammonium) are the largest contributor to PM2.5 during the haze period, while sulfate shows the largest enhancement ratio of 5.4 from the clean to haze period. The nested‐grid GEOS‐Chem model reproduces the distribution of PM2.5 and simulates up to 364 µg/m3 of daily maximum PM2.5. Yet on average, the model is a factor of 3 and 4 lower in PM2.5 and fails to capture the large sulfate enhancement from the clean to haze period. A doubling of SO2 emissions over North China, along with daily meteorology corrections, would be required to reconcile model results with surface SO2 observations, but it is not sufficient to explain the model discrepancy in sulfate. Heterogeneous uptake of SO2 on deliquesced aerosols is proposed as an additional source of sulfate under high‐relative humidity conditions during the haze period. Parameterizing this process in the model improves the simulated spatial distribution and results in a 70% increase of sulfate enhancement ratio and a 120% increase in sulfate fraction in PM2.5. Combined adjustments in emissions, meteorology, and sulfate chemistry lead to higher sulfate by a factor of 3 and 50% higher PM2.5, significantly reducing the model's low bias during the haze. Key Points Sulfate enhancement is the chemical driver for January 2013 winter hazeModel simulates 364 µg/m3 daily maximum PM2.5 but low on sulfate fractionHeterogeneous oxidation identified as additional source of sulfate during haze