Mixing state of individual submicron carbon-containing particles during spring and fall seasons in urban Guangzhou, China: a case study

G Zhang,M Li,J Fu,L Y Chan,L Li,Z Zhou,X Wang,X Bi,G Sheng

doi:10.5194/acp-13-4723-2013

Abstract

Abstract. Growing evidence suggests that the size-resolved mixing state of carbon-containing particles is very critical in determining their optical properties, atmospheric lifetime, and impact on the environment. However, still little is known about the mixing state of particles in the urban area of the Pearl River Delta (PRD) region, China. To investigate the mixing state of submicron carbon-containing particles, measurements were carried out during spring and fall periods of 2010 using a single-particle aerosol mass spectrometer (SPAMS). Approximately 700 000 particles for each period were detected. This is the first report on the size-resolved mixing state of carbon-containing particles by direct observations in the PRD region. Cluster analysis of single-particle mass spectra was applied to identify carbon-containing particle classes. These classes represented ~80% and ~90% of all the detected particles for spring and fall periods, respectively. Carbon-containing particle classes mainly consisted of biomass/biofuel burning particles (Biomass), organic carbon (OC), fresh elemental carbon (EC-fresh), internally mixed OC and EC (ECOC), internally mixed EC with sulfate (EC-Sulfate), vanadium-containing ECOC (V-ECOC), and amines-containing particles (Amine). In spring, the top three ranked carbon-containing particle classes were ECOC (26.1%), Biomass (23.6%) and OC (10%), respectively. However, the fraction of Biomass particles increased remarkably and predominated (61.0%), while the fraction of ECOC (3.0%) and V-ECOC (0.1%) significantly decreased in fall. To highlight the influence of monsoon on the properties of carbon-containing particles in urban Guangzhou, their size distributions, mixing state, and aerosol acidity were compared between spring and fall seasons. In addition, a case study was also performed to investigate how the formation of fog and haze influenced the mixing state of carbon-containing particles. These results could improve our understanding of the mixing state of carbon-containing particles, and may also be helpful in modeling the climate forcing of aerosol in the PRD region.

Highlights

Hydrology and Carbonaceous aerosols strongly affect the visibility and enSystem ergy balance of Earth byEarth either scattering or absorbing solar radiation (Jacobson, 2001; Ramanathan and Carmichael, 2008)
Carbon-containing particles consisted of particle classes corresponding to biomass/biofuel burning particles (Biomass), organic carbon (OC)-dominant particles lacking or with negligible elemental carbon (EC) signals (OC), internally mixed OC and EC (ECOC), fresh EC
Particles (EC-fresh), EC-dominant particles mainly mixed with sulfate (EC-Sulfate), and vanadium-containing ECOC

Summary

Introduction

Hydrology and Carbonaceous aerosols strongly affect the visibility and enSystem ergy balance of Earth byEarth either scattering or absorbing solar radiation (Jacobson, 2001; Ramanathan and Carmichael, 2008). We applied real-time single-particle aerosol mass spectrometer (SPAMS) measurements to reveal the major single-particle classes of carbon-containing particles, and to explore the seasonal variability of their number fraction as a function of vacuum aerodynamic diameter (dva ), aerosol mixing state with secondary species, and particle acidity in the spring and fall of 2010 as a case study, in the urban area of the PRD region.

Results

Conclusion