Transport pathways for Asian pollution outflow over the Pacific: Interannual and seasonal variations

Hongyu Liu,Robert M Yantosca,Glen W Sachse,Bryan N Duncan,Daniel J Jacob,Isabelle Bey

doi:10.1029/2002jd003102

Abstract

The meteorological pathways contributing to Asian pollution outflow over the Pacific are examined with a global three‐dimensional model analysis of CO observations from the Transport and Chemical Evolution over the Pacific (TRACE‐P) aircraft mission (February–April 2001). The model is used also to place the TRACE‐P observations in an interannual (1994–2001) and seasonal context. The major process driving Asian pollution outflow in spring is frontal lifting ahead of southeastward‐moving cold fronts (the leading edge of cold surges) and transport in the boundary layer behind the cold fronts. Orographic lifting over central and eastern China combines with the cold fronts to promote the transport of Chinese pollution to the free troposphere. Outflow of seasonal biomass burning in Southeast Asia during spring takes place mostly by deep convection but also by northeastward transport and frontal lifting, mixing with the anthropogenic outflow. Boundary layer outflow over the western Pacific is largely devoid of biomass burning influence. European and African (biomass burning) plumes in Asian outflow during TRACE‐P were weak (<60 ppbv and 20 ppbv CO, respectively) and were not detectable in the observations because of superposition of the much larger Asian pollution signal. Spring 2001 (La Niña) was characterized by unusually frequent cold surge events in the Asian Pacific rim and strong convection in Southeast Asia, leading to unusually strong boundary layer outflow of anthropogenic emissions and convective outflow of biomass burning emissions in the upper troposphere. The Asian outflow flux of CO to the Pacific is found to vary seasonally by a factor of 3–4 (maximum in March and minimum in summer). The March maximum results from frequent cold surge events and seasonal biomass burning emissions.

Highlights

[2] Rapid industrialization is taking place over the Asian continent, and energy consumption in Asia is expected to continue to increase in the few decades
Bey et al [2001b] examined Asian outflow over the western Pacific during the NASA Pacific Exploratory Mission-West B (PEM-West B) aircraft mission (February –March, 1994). They found that frontal lifting of pollution over central and eastern China ahead of eastward moving cold fronts, followed by westerly transport in the lower free troposphere (FT), was the principal process responsible for export of both anthropogenic and biomass burning pollution from Asia. They further found that effluents from seasonal biomass burning in Southeast Asia were mixed with anthropogenic pollution in the FT frontal outflow, and that the boundary layer (BL) outflow was mainly anthropogenic and confined to north of 35°N
Carbon monoxide (CO) is an excellent tracer for long-range pollution transport [Staudt et al, 2001; Bey et al, 2001b] because (1) it is a general product of incomplete combustion, with major sources from vehicles, biofuels, and biomass burning [Streets et al, 2003], (2) it has a lifetime of a few months, sufficiently long to track pollution plumes on synoptic and intercontinental scales, but sufficiently short to provide strong pollution enhancements in these plumes relative to background, and (3) it can be measured with high precision and temporal resolution

Summary

Published Version Citable link Terms of Use

“Transport Pathways for Asian Pollution Outflow over the Pacific: Interannual and Seasonal Variations.”. Transport pathways for Asian pollution outflow over the Pacific: Interannual and seasonal variations. The major process driving Asian pollution outflow in spring is frontal lifting ahead of southeastward-moving cold fronts (the leading edge of cold surges) and transport in the boundary layer behind the cold fronts. Outflow of seasonal biomass burning in Southeast Asia during spring takes place mostly by deep convection and by northeastward transport and frontal lifting, mixing with the anthropogenic outflow. Spring 2001 (La Nina) was characterized by unusually frequent cold surge events in the Asian Pacific rim and strong convection in Southeast Asia, leading to unusually strong boundary layer outflow of anthropogenic emissions and convective outflow of biomass burning emissions in the upper troposphere.

Introduction

Findings

Summary and Conclusions