Optical Properties of Aerosols and Implications for Radiative Effects in Beijing During the Asia‐Pacific Economic Cooperation Summit 2014

Zhou, Yaqing; Wang, Qiyuan; Huang, Ru‐Jin; Liu, Suixin; Tie, Xuexi; Su, Xiaoli; Niu, Xinyi; Zhao, Zi-Long; Ni, Haiyan; Wang, Meng; Zhang, Yonggang; Cao, Junji

doi:10.1002/2017jd026997

Cited by 15 publications

(7 citation statements)

References 58 publications

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“…This should be attributed to the lower PM2.5 loadings during the NCCPC control period. The DRF reduction ratio (26.3%) during the NCCPC control period is smaller than the value during the APEC period (61.3%, Zhou et al, 2017). Furthermore, the DRF values can be as high as -24.7 and -28.2 W m -2 during the PE1 and PE2, respectively.…”

Section: Impacts Of Pm25 Emission Reduction On Aerosol Radiative Effmentioning

confidence: 76%

“…components to bext are found. For example, Li et al (2013) have reported that (NH4)2SO4 (41%) has the largest contribution to bext during the Olympics, followed by NH4NO3 (23%), OM (17%), and EC (9%); Zhou et al (2017) have found that OM 49%is the largest contributor to bext, followed by NH4NO3 (19%), (NH4)2SO4 (13%), and EC (12%). These differences may be attributed to the different reductions in PM2.5 chemical species and the variable RH among studies which can influence the hygroscopic properties of sulfate and nitrate.…”

Section: Impacts Of Pm25 Emission Reduction On Aerosol Radiative Effmentioning

confidence: 99%

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Impacts of short-term mitigation measures on PM2.5 and radiative effects: a case study from a regional background site near Beijing, China

Wang¹,

Liu²,

Li³

et al. 2018

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Abstract. An intensive measurement campaign was conducted in a regional background site near Beijing during the 19th National Congress of the Communist Party of China (NCCPC) to investigate the effectiveness of short-term mitigation measures on PM2.5 and aerosol direct radiative forcing (DRF). Average mass concentration of PM2.5 and its major chemical composition are decreased by 20.6&#8211;43.1&#8201;% during the NCCPC control period compared with the non-control period. When considering days with the stable meteorological conditions, larger reduction of PM2.5 is found compared with that for all days. Further, a positive matrix factorization receptor model shows that the mass concentrations of PM2.5 from traffic-related emissions, biomass burning, industry processes, and mineral dust are reduced by 38.5&#8211;77.8&#8201;% during the NCCPC control period compared with the non-control period. However, there is no significant difference in PM2.5 from coal burning between these two periods, and an increasing trend of PM2.5 mass from secondary inorganic aerosol is found during the NCCPC control period. Two pollution episodes were occurred subsequently after the NCCPC control period. One is dominated by secondary inorganic aerosol, and the WRF-Chem model shows that the Beijing-Tianjin-Hebei (BTH) region contributes 73.6&#8201;% of PM2.5 mass; the other is mainly caused by biomass burning, and the BTH region contributes 46.9&#8201;% of PM2.5 mass. Calculations based on a revised IMPROVE method show that organic matter (OM) is the largest contributor to the light extinction coefficient (bext<\\sub>) during the non-control period while NH4NO3 is the dominant contributor during the NCCPC control period. The Tropospheric Ultraviolet and Visible radiation model reveals that the average DRF values at the Earth's surface are &#8722;14.0 and &#8722;19.3&#8201;W&#8201;m-2 during the NCCPC control and non-control periods, respectively, and the reduction ratios of DRF due to the decrease in PM2.5 components vary from 22.7&#8211;46.7&#8201;% during the NCCPC control period. Our study would further provide valuable information and dataset to help controlling the air pollution and alleviating the cooling effects of aerosols at the surface in Beijing.

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Section: Impacts Of Pm25 Emission Reduction On Aerosol Radiative Effmentioning

confidence: 76%

Section: Impacts Of Pm25 Emission Reduction On Aerosol Radiative Effmentioning

confidence: 99%

Impacts of short-term mitigation measures on PM2.5 and radiative effects: a case study from a regional background site near Beijing, China

Wang¹,

Liu²,

Li³

et al. 2018

Preprint

Self Cite

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“…In contrast, receptor models can be utilised to conduct multiple optical source apportionment of aerosol. Several studies have used a combination of the receptor model and MLR to indirectly identify sources of aerosol b scat , b abs , and b ext (Cao et al, 2012;Tian et al, 2020;Zhou et al, 2017). For example, Zhou et al (2017) first used positive matrix factorisation analysis to quantify the mass contributions of aerosol from secondary aerosol, biomass burning, trafficrelated emissions, and coal combustion based on the sole chemical species, and MLR was then used to apportion the contribution of each source to b scat and b abs .…”

Section: Introductionmentioning

confidence: 99%

Measurement report: The importance of biomass burning in light extinction and direct radiative effect of urban aerosol during the COVID-19 lockdown in Xi'an, China

et al. 2022

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Abstract. Due to the complexity of emission sources, a better understanding of aerosol optical properties is required to mitigate climate change in China. Here, an intensive real-time measurement campaign was conducted in an urban area of China before and during the COVID-19 lockdown in order to explore the impacts of anthropogenic activities on aerosol light extinction and the direct radiative effect (DRE). The mean light extinction coefficient (bext) decreased from 774.7 ± 298.1 Mm−1 during the normal period to 544.3 ± 179.4 Mm−1 during the lockdown period. A generalised additive model analysis indicated that the large decline in bext (29.7 %) was due to sharp reductions in anthropogenic emissions. Chemical calculation of bext based on a ridge regression analysis showed that organic aerosol (OA) was the largest contributor to bext in both periods (45.1 %–61.4 %), and the contributions of two oxygenated OAs to bext increased by 3.0 %–14.6 % during the lockdown. A hybrid environmental receptor model combined with chemical and optical variables identified six sources of bext. It was found that bext from traffic-related emissions, coal combustion, fugitive dust, the nitrate and secondary OA (SOA) source, and the sulfate and SOA source decreased by 21.4 %–97.9 % in the lockdown, whereas bext from biomass burning increased by 27.1 %, mainly driven by the undiminished need for residential cooking and heating. An atmospheric radiative transfer model was further used to illustrate that biomass burning, rather than traffic-related emissions, became the largest positive effect (10.0 ± 10.9 W m−2) on aerosol DRE in the atmosphere during the lockdown. Our study provides insights into aerosol bext and DRE from anthropogenic sources, and the results imply the importance of controlling biomass burning for tackling climate change in China in the future.

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“…In contrast, receptor models can be utilized to resolve multiple optical source apportionment of aerosol. Several studies used a combination of the receptor model and MLR to indirectly identify sources of aerosol b scat , b abs , and b ext (Cao et al, 2012;Tian et al, 2020;Zhou et al, 2017). For example, Zhou et al (2017) firstly used positive matrix factorization analysis to quantify the mass contributions of aerosol from secondary aerosol, biomass burning, traffic-related emissions, and coal burning based on the sole chemical species, and then the MLR was used to apportion the contribution of each source to b scat and b abs .…”

mentioning

confidence: 99%

“…Several studies used a combination of the receptor model and MLR to indirectly identify sources of aerosol b scat , b abs , and b ext (Cao et al, 2012;Tian et al, 2020;Zhou et al, 2017). For example, Zhou et al (2017) firstly used positive matrix factorization analysis to quantify the mass contributions of aerosol from secondary aerosol, biomass burning, traffic-related emissions, and coal burning based on the sole chemical species, and then the MLR was used to apportion the contribution of each source to b scat and b abs . In addition, recent studies have attempted to conduct direct optical source apportionment by combining aerosol chemical species with optical coefficients in one receptor model (Forello et al, 2019;Q.…”

mentioning

confidence: 99%

Measurement report: The importance of biomass burning in light extinction and direct radiative effect of urban aerosol during the COVID-19 lockdown in China

Tian

Wang

Liu

et al. 2021

Preprint

Self Cite

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Abstract. To mitigate climate change in China, a better understanding of optical properties of aerosol is required due to the complexity in emission sources. Here, an intensive real-time measurement was conducted in an urban area of China before and during the lockdown of Coronavirus Disease 2019 (COVID-19), to explore the impacts of anthropogenic activities on aerosol light extinction and direct radiative effect (DRE). The mean light extinction coefficient (bext) reduced from 774.7 ± 298.1 Mm−1 during the normal period to 544.3 ± 179.4 Mm−1 during the lockdown period. The generalized addictive model analysis indicated that the large decline of bext (29.7 %) was entirely attributed to the sharp reductions in anthropogenic emissions. Chemical calculation of bext based on the ridge regression analysis showed that organic aerosol (OA) was the largest contributor to bext in both periods (45.1–61.4 %), and contributions of two oxygenated OAs to bext increased by 3.0–14.6 % during the lockdown. A hybrid environmental receptor model combining with chemical and optical variables identified six sources of bext. It was found that bext from traffic-related emission, coal combustion, fugitive dust, nitrate plus secondary OA (SOA) source, and sulfate plus SOA source decreased by 21.4–97.9 % in the lockdown, whereas bext from biomass burning increased by 27.1 % mainly driven by undiminished needs of residential cooking and heating. The atmospheric radiative transfer model was further used to illustrate that biomass burning instead of traffic-related emission became the largest positive effect (10.0 ± 10.9 W m−2) on aerosol DRE in the atmosphere during the lockdown. Our study provides insights into aerosol bext and DRE from anthropogenic sources, and the results implied the importance of biomass burning for tackling climate change in China in the future.

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Optical Properties of Aerosols and Implications for Radiative Effects in Beijing During the Asia‐Pacific Economic Cooperation Summit 2014

Cited by 15 publications

References 58 publications

Impacts of short-term mitigation measures on PM<sub>2.5</sub> and radiative effects: a case study from a regional background site near Beijing, China

Impacts of short-term mitigation measures on PM<sub>2.5</sub> and radiative effects: a case study from a regional background site near Beijing, China

Measurement report: The importance of biomass burning in light extinction and direct radiative effect of urban aerosol during the COVID-19 lockdown in Xi'an, China

Measurement report: The importance of biomass burning in light extinction and direct radiative effect of urban aerosol during the COVID-19 lockdown in China

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Optical Properties of Aerosols and Implications for Radiative Effects in Beijing During the Asia‐Pacific Economic Cooperation Summit 2014

Cited by 15 publications

References 58 publications

Impacts of short-term mitigation measures on PM&lt;sub&gt;2.5&lt;/sub&gt; and radiative effects: a case study from a regional background site near Beijing, China

Impacts of short-term mitigation measures on PM&lt;sub&gt;2.5&lt;/sub&gt; and radiative effects: a case study from a regional background site near Beijing, China

Measurement report: The importance of biomass burning in light extinction and direct radiative effect of urban aerosol during the COVID-19 lockdown in Xi'an, China

Measurement report: The importance of biomass burning in light extinction and direct radiative effect of urban aerosol during the COVID-19 lockdown in China

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Impacts of short-term mitigation measures on PM<sub>2.5</sub> and radiative effects: a case study from a regional background site near Beijing, China

Impacts of short-term mitigation measures on PM<sub>2.5</sub> and radiative effects: a case study from a regional background site near Beijing, China