During the winter of 2015, there was a strong El Nino (ENSO) event, resulting in significant anomalies for meteorological conditions in China. Analysis shows that the meteorological conditions in December 2015 (compared to December 2014) had several important anomalies, including the following: (1) the surface southeasterly winds were significantly enhanced in the North China Plain (NCP); (2) the precipitation was increased in the south of eastern China; and (3) the wind speeds were decreased in the middle-north of eastern China, while slightly increased in the south of eastern China. These meteorological anomalies produced important impacts on the aerosol pollution in eastern China. In the NCP region, the PM2.5 concentrations were significantly increased, with a maximum increase of 80–100 μg m−3. A global chemical/transport model (MOZART-4) was applied to study the individual contribution of the changes in winds and precipitation to PM2.5 concentrations. This study suggests that the 2015El Nino event had significant effects on air pollution in eastern China, especially in the NCP region, including the capital city of Beijing, in which aerosol pollution was significantly enhanced in the already heavily polluted capital city of China.
Abstract. Severe ozone (O3) pollution episodes plague a few regions in eastern
China at certain times of the year, e.g., the Yangtze River Delta (YRD). However, the formation
mechanisms, including meteorological factors, contributing to these severe pollution events
remain elusive. A severe summer smog stretched over the YRD region from
22 to 25 August 2016. This event displayed hourly surface O3 concentrations that
exceeded 300 µg m−3 on 25 August in Nanjing, an urban area in the western
YRD. The weather pattern during this period was characterized by near-surface
prevailing easterly winds and continuous high air temperatures. The formation
mechanism responsible for this O3 pollution episode over the YRD region, particularly
the extreme values over the western YRD, was investigated using
observation data and by running simulations with the Weather Research and Forecasting
model with Chemistry (WRF-Chem). The results showed that the extremely high
surface O3 concentration in the western YRD area on 25 August was
largely due to regional O3 transport in the nocturnal residual
layer (RL) and the diurnal change in the atmospheric boundary layer.
On 24 August, high O3 levels, with peak values of
220 µg m−3, occurred in the daytime mixing layer over the eastern YRD region. During
nighttime from 24 to 25 August, a shallow stable boundary layer formed near
the surface which decoupled the RL above it from the surface. Ozone in the
decoupled RL remained quite constant, which resulted in an O3-rich
“reservoir” forming in this layer. This reservoir persisted due to the absence of O3 consumption from nitrogen
oxide (NO) titration or dry deposition during nighttime. The prevailing
easterly winds in the lower troposphere governed the regional transport of
this O3-rich air mass in the nocturnal RL from the eastern to the western YRD. As
the regional O3 transport reached the RL over the western YRD, O3
concentrations in the RL accumulated and rose to 200 µg m−3 over the
western Nanjing site during the sunrise hours on 25 August. The development of
the daytime convective boundary layer after sunrise resulted in the
disappearance of the RL, as the vertical mixing in the convective boundary layer
uniformly redistributed O3 from the upper levels via the
entrainment of O3-rich RL air down to the O3-poor air at the ground.
This net downward transport flux reached up to 35 µg m−3 h−1,
and contributed a considerable surface O3 accumulation, resulting in severe daytime
O3 pollution during the summer smog event on 25 August in the western YRD region.
The mechanism of regional O3 transport through the nocturnal RL revealed
in this study has great implications regarding understanding O3 pollution
and air quality change.
Severe ozone (O3) episodes occur frequently in Shanghai during late-summers. We define geopotential height averaged over the key area region (122.5°E-135°E, 27.5°N -35°N) at 500 hPa as a WPSH_SHO3 index which has high positive correlation with surface O3 concentration in Shanghai. In addition, the index has a significant long-term increasing trend during the recent 60 years. Analysis shows the meteorological conditions under the strong WPSH_SHO3 climate background (compared to the weak background) have several important anomalies: (1) A strong WPSH center occurs over the key area region. (2) The cloud cover is less, resulting in high solar radiation and low humidity, enhancing the photochemical reactions of O3. (3) The near-surface southwesterly winds are more frequent, enhancing the transport of upwind pollutants and O3 precursors from polluted regions to Shanghai and producing higher O3 chemical productions. This study suggests that the global climate change could lead to a stronger WPSH in the key region, enhancing ozone pollution in Shanghai. A global chemical/transport model (MOZART-4) is applied to show that the O3 concentrations can be 30 ppbv higher under a strong WPSH_SHO3 condition than a weak condition, indicating the important effect of the global climate change on local air pollution in Shanghai.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.