To control the spread of the 2019 novel coronavirus (COVID-19), China imposed nationwide restrictions on the movement of its population (lockdown) after the Chinese New Year of 2020, leading to large reductions in economic activities and associated emissions. Despite such large decreases in primary pollution, there were nonetheless several periods of heavy haze pollution in East China, raising questions about the well-established relationship between human activities and air quality. Here, using comprehensive measurements and modeling, we show the haze during the COVID lockdown were driven by enhancements of secondary pollution. In particular, large decreases in NOx emissions from transportation increased ozone and nighttime NO3 radical formation, and these increases in atmospheric oxidizing capacity in turn facilitated the formation of secondary particulate matter. Our results, afforded by the tragic natural experiment of the COVID-19 pandemic, indicate that haze mitigation depends upon a coordinated and balanced strategy for controlling multiple pollutants.
Recent evidence shows that carbon emissions in China are likely to peak ahead of 2030. However, the social and economic impacts of such an early carbon peak have rarely been assessed. Here we focus on the economic costs and health benefits of different carbon mitigation pathways, considering both possible socio-economic futures and varying ambitions of climate policies. We find that an early peak before 2030 in line with the 1.5 °C target could avoid ~118,000 and ~614,000 PM2.5 attributable deaths under the Shared Socioeconomic Pathway 1, in 2030 and 2050, respectively. Under the 2 °C target, carbon mitigation costs could be more than offset by health co-benefits in 2050, bringing a net benefit of $393–$3,017 billion (in 2017 USD value). This study not only provides insight into potential health benefits of an early peak in China, but also suggests that similar benefits may result from more ambitious climate targets in other countries.
Low clouds play a key role in the Earth-atmosphere energy balance and influence agricultural production and solar-power generation. Smoke aloft has been found to enhance marine stratocumulus through aerosol-cloud interactions, but its role in regions with strong human activities and complex monsoon circulation remains unclear. Here we show that biomass burning aerosols aloft strongly increase the low cloud coverage over both land and ocean in subtropical southeastern Asia. The degree of this enhancement and its spatial extent are comparable to that in the Southeast Atlantic, even though the total biomass burning emissions in Southeast Asia are only one-fifth of those in Southern Africa. We find that a synergetic effect of aerosol-cloud-boundary layer interaction with the monsoon is the main reason for the strong semi-direct effect and enhanced low cloud formation in southeastern Asia.
Despite the large reduction in anthropogenic activities due to the outbreak of
COVID-19, air quality in China has witnessed little improvement and featured great
regional disparities. Here, by combining observational data and simulations, this work
aims to understand the diverse air quality response in two city clusters, Yangtze River
Delta region (YRD) and Pearl River Delta region (PRD), China. Though there was a
noticeable drop in primary pollutants in both the regions, differently, the maximum
daily 8 h average ozone (O
3
) soared by 20.6–76.8% in YRD but decreased
by 15.5–28.1% in PRD. In YRD, nitrogen oxide (NOx) reductions enhanced
O
3
accumulation and hence increased secondary aerosol formation. Such an
increment in secondary organic and inorganic aerosols under stationary weather reached
up to 36.4 and 10.2%, respectively, which was further intensified by regional transport.
PRD was quite the opposite. The emission reductions benefited PRD air quality, while
regional transport corresponded to an increase of 17.3 and 9.3% in secondary organic and
inorganic aerosols, respectively. Apart from meteorology, the discrepancy in
O
3
–VOCs–NOx relationships determined the different
O
3
responses, indicating that future emission control shall be regionally
specific, instead of one-size-fits-all cut. Overall, the importance of regionally
coordinated and balanced control strategy for multiple pollutants is highly
emphasized.
The impact of the East Asian monsoon (EAM) on climatology and interannual variability of tropospheric ozone (O 3 ) over the coastal South China was investigated by analyzing 11 years of ozonesonde data over Hong Kong with the aid of Lagrangian dispersion modeling of carbon monoxide and calculation of an EAM index. It was found that the seasonal cycle of O 3 in the lower troposphere is highly related to the EAM over the study region. Ozone enhancements in the free troposphere are associated with the monsoon-induced transport of pollutants of continental anthropogenic and biomass burning origins. Lower tropospheric O 3 levels showed high interannual variability, with an annual averaged amplitude up to 61% of averaged concentrations in the boundary layer (0-1 km altitudes) and 49% below 3 km altitude. In spring and autumn, the interannual variability in boundary layer O 3 levels was predominately influenced by the EAM intensity, with high O 3 mixing ratios associated with northeasterly circulation anomalies.
Abstract. Anthropogenic fossil fuel (FF) combustion, biomass burning (BB) and desert
dust are the main sources of air pollutants around the globe but are particularly
intensive and important for air quality in Asia in spring. In this study, we
investigate the vertical distribution, transport characteristics, source
contribution and meteorological feedback of these aerosols in a unique
pollution episode that occurred in eastern Asia based on various measurement data
and modeling methods. In this episode, the Yangtze River Delta (YRD) in
eastern China experienced persistent air pollution, dramatically changing
from secondary fine particulate pollution to dust pollution in late March
2015. The Eulerian and Lagrangian models were conducted to investigate the
vertical structure, transport characteristics and mechanisms of the
multi-scale, multisource and multiday air pollution episode. The regional
polluted continental aerosols mainly accumulated near the surface, mixed with
dust aerosol downwash from the upper planetary boundary layer (PBL) and
middle–lower troposphere (MLT), and further transported by large-scale cold
fronts and warm conveyor belts. BB smoke from Southeast Asia was transported
by westerlies around the altitude of 3 km from southern China, was further mixed
with dust and FF aerosols in eastern China and experienced long-range
transport over the Pacific. These pollutants could all be transported to the YRD
region and cause a structure of multilayer pollution there. These
pollutants could also cause significant feedback with MLT meteorology and
then enhance local anthropogenic pollution. This study highlights the
importance of intensive vertical measurement in eastern China and the
downwind Pacific Ocean and raises the need for quantitative understanding of
environmental and climate impacts of these pollution sources.
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