Mixing layer height on the North China Plain and meteorological evidence of serious air pollution in southern Hebei

Zhu, Xinhua; Tang, Guiqian; Guo, Jianping; Hu, Bo; Song, Tao; Wang, Lili; Xin, Jinyuan; Gao, Wenkang; Münkel, Christoph; Schäfer, Klaus; Li, Xin; Wang, Yuesi

doi:10.5194/acp-18-4897-2018

Cited by 88 publications

(34 citation statements)

References 60 publications

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“…As the lowest part of the troposphere, the planetary boundary layer (PBL) is strongly influenced by the turbulence and complex geophysical processes due to its close contact with the Earth's surface (Garratt, ; Stull, ). The coupling of the PBL and the surface is largely modulated by turbulent exchange processes, including the intensive vertical mixing of momentum, water, heat, and air pollution between surface and troposphere (Li et al, ; Luan et al, ; Mao et al, ; Zhu et al, ). The role of aerosol in modulating the evolution of PBL has been increasingly appreciated due to the considerable radiative effect (Guo, Deng, et al, ; Li et al, ; Patil et al, ; Wang et al, ; Xu et al, ; Zheng et al, ), especially the dome effect caused by the absorbing aerosol (e.g., black carbon) that tends to stabilize the PBL (Ding et al, ; Jiang et al, ).…”

Section: Introductionmentioning

confidence: 99%

On the Relationship Between Aerosol and Boundary Layer Height in Summer in China Under Different Thermodynamic Conditions

Lou

Guo

Wang

et al. 2019

Earth and Space Science

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The observed relationships between boundary layer height (BLH) and PM2.5 on a national scale remain unclear due to the dearth of observations. Here we investigated this relationship from a unique perspective of thermodynamic stability in the planetary boundary layer (PBL), using summertime (June–August) soundings from China for the period from 2014 to 2017. For all three times of soundings (0800, 1400, and 2000 Beijing time [BJT]), positive (negative) PM2.5 concentrations anomalies were found to correlate with negative (positive) BLHs anomalies relative to daily means. The negative correlation was strongest at 1400 BJT, followed by 2000 BJT and 0800 BJT. Overall, the PM2.5 was found to nonuniformly anticorrelate with BLH across China at 0800 and 2000 BJT. The strongest anticorrelation occurred in the North China Plain at 1400 BJT, in sharp contrast to the much weaker correlation in other regions characterized by much less polluted regions. The averaged PM2.5 in neutral boundary layers was higher than that in convective boundary layers (CBLs). The CBL, where the anticorrelation was the strongest, was conducive to dissipating more aerosol in the heavily polluted area in China than neutral boundary layer. The higher CBL formed under low cloud cover, low surface humidity, and strong wind speed was favorable for the dispersion of aerosol, in contrast to the stable boundary layers that happen under the highest cloud cover. Also, positive correlation was seen between stable boundary layer and PM2.5. The findings call for attention that the thermodynamical condition of PBL should be considered when examining the aerosol‐PBL interactions.

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Section: Introductionmentioning

confidence: 99%

On the Relationship Between Aerosol and Boundary Layer Height in Summer in China Under Different Thermodynamic Conditions

Lou

Guo

Wang

et al. 2019

Earth and Space Science

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“…Ventilation coefficient is an essential parameter for simultaneous quantification of vertical dispersion and advection in context with air pollution studies (Zhu et al, 2018). Based on the ML height and wind speed measurements the monthly average ventilation coefficient is calculated to gain further insight into the horizontal and vertical mixing capacity of the lower atmosphere (Tang et al, 2015;Mues et al, 2017).…”

Section: Ventilation Coefficientmentioning

confidence: 99%

Mixing Layer Height Retrievals From MiniMPL Measurements in the Chiang Mai Valley: Implications for Particulate Matter Pollution

et al. 2019

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“…As pollution worsens, the contribution of the surrounding areas to the PM 2.5 in Beijing rose from 52 % to 65 % per month on average in 2016 (Zhang et al, 2018). However, during heavy pollution, the TF decreases in Beijing (Chang et al, 2018;Tang et al, 2015;Zhu et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Mixing layer transport flux of particulate matter in Beijing, China

et al. 2019

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Abstract. Quantifying the transport flux (TF) of atmospheric pollutants plays an important role in understanding the causes of air pollution and in making decisions regarding the prevention and control of regional air pollution. In this study, the mixing layer height (MLH) and wind profile were measured by a ceilometer and Doppler wind radar, respectively, and the characteristics of the atmospheric dilution capability were analyzed using these two datasets. The ventilation coefficient (VC) appears to be the highest in the spring (3940±2110 m2 s−1) and lower in the summer (2953±1322 m2 s−1), autumn (2580±1601 m2 s−1) and winter (2913±3323 m2 s−1). Combined with the backscatter measured by the ceilometer, vertical profiles of the PM2.5 concentration were obtained and the PM2.5 TF in the mixing layer was calculated. The TF was the highest in the spring at 4.33±0.69 mg m−1 s−1 and lower in the summer, autumn and winter, when the TF values were 2.27±0.42, 2.39±0.45 and 2.89±0.49 mg m−1 s−1, respectively. Air pollutants transport mainly occurs between 14:00 and 18:00 LT. The TF was large in the pollution transition period (spring: 5.50±4.83 mg m−1 s−1; summer: 3.94±2.36 mg m−1 s−1; autumn: 3.72±2.86 mg m−1 s−1; winter: 4.45±4.40 mg m−1 s−1) and decreased during the heavy pollution period (spring: 4.69±4.84 mg m−1 s−1; summer: 3.39±1.77 mg m−1 s−1; autumn: 3.01±2.40 mg m−1 s−1; winter: 3.25±2.77 mg m−1 s−1). Our results indicate that the influence of the air pollutants transport in the southern regions should receive more focus in the transition period of pollution, while local emissions should receive more focus in the heavy pollution period.

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Mixing layer height on the North China Plain and meteorological evidence of serious air pollution in southern Hebei

Cited by 88 publications

References 60 publications

On the Relationship Between Aerosol and Boundary Layer Height in Summer in China Under Different Thermodynamic Conditions

On the Relationship Between Aerosol and Boundary Layer Height in Summer in China Under Different Thermodynamic Conditions

Mixing Layer Height Retrievals From MiniMPL Measurements in the Chiang Mai Valley: Implications for Particulate Matter Pollution

Mixing layer transport flux of particulate matter in Beijing, China

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