Abstract

Beijing suffers from poor air quality particularly during wintertime haze episodes when concentrations of PM2.5 can peak at > 400 ug/m3. Black carbon (BC), an aerosol which strongly absorbs solar radiation can make up to 10 % of PM2.5 in Beijing. Black carbon is of interest due to its climatic and health impacts. Black carbon has also been found to impact planetary boundary layer (PBL) meteorology. Through interacting with radiation and altering the thermal profile of the lower atmosphere, BC can either suppress or enhance PBL development to various degrees depending on the properties and altitude of the BC layer.Previous research assessing the impact of BC on PBL meteorology has been investigated through the use of regional models which are limited both by resolution and the chosen boundary layer schemes. In this work, we apply a high resolution coupled large eddy simulation-aerosol-radiation model (UCLALES-SALSA) to quantify the impact of black carbon at different altitudes on PBL dynamics using conditions from a specific haze episode which occurred from 1st–4th Dec 2016 in Beijing. Results presented in this paper quantify the heating rate of BC at various altitudes to be between 0.01 and 0.016 K/h per μg/m3 of BC, increasing with altitude but decreasing across the PBL. Through utilising a high resolution model which explicitly calculates turbulent dynamics, this paper showcases the impact of BC on PBL dynamics both within and above the PBL. These results show that BC within the PBL increases maximum PBL height by 0.4 % but that the same loading of BC above the PBL can suppress PBL height by 6.5 %. Furthermore, when BC is present throughout the column the impact of BC suppressing PBL development is further maximised, with BC causing a 17 % decrease in maximum PBL height compared to only scattering aerosols. Combining these results in this paper, we present a mechanism through which BC may play a prominent role in the intensity and longevity of Beijing’s pollution episodes.

Highlights

  • 20 Beijing, a megacity situated in the North China Plain, experiences extremely poor air quality

  • Our results show that including Black carbon (BC) both within and 270 above the planetary boundary layer (PBL) causes a large reduction in PBL height (17 %) compared to no BC (Table 4)

  • 295 The results here show that BC causes heating in the atmosphere, and that absorption of solar radiation by BC has the largest impact on the temperature profile of the PBL compared to the effect of scattering aerosols

Read more

Summary

Introduction

20 Beijing, a megacity situated in the North China Plain, experiences extremely poor air quality. Absorbing aerosol particles can lead to warming of the air above the surface This alters the thermal profile of the atmosphere and reduces buoyant turbulence, suppressing PBL development and allowing aerosols to accumulate in a shallow PBL. In a 1D modelling study, Wang et al (2018) found that BC aloft was essential in the suppression of PBL height, with surface BC increasing both turbulence and 70 PBL height They found that a BC layer close to the PBL top and internal mixing of BC with scattering aerosols (sulphate, nitrate, ammonium) significantly enhanced the dome effect of BC, leading to a potential reduction in PBL height of 15 %.

Model Description
125 2.2 Experimental Setup
Case 2- Varying initial conditions 160
Results
Discussion
Findings
Conclusions

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.