Abstract
Abstract. The present paper investigates the diurnal and seasonal variability of the aerosol total number concentration, number and volume size distribution between 10 nm and 10 μm, from a combination of a scanning mobility particle sizer (SMPS) and an optical counter (OPC), performed over a two-year period (January 2006–February 2008) at the Nepal Climate Observatory-Pyramid (NCO-P) research station, (5079 m a.s.l.). The annual average number concentration measured over the two-year period at the NCO-P is 860 cm−3. Total concentrations show a strong seasonality with maxima during pre-monsoon and post-monsoon seasons and minima during the dry and monsoon seasons. A diurnal variation is also clearly observed, with maxima between 09:00 and 12:00 UTC. The aerosol concentration maxima are mainly due to nucleation processes during the post-monsoon season, as witnessed by high nucleation mode integrated number concentrations, and to transport of high levels of pollution from the plains by valley breezes during the pre-monsoon season, as demonstrated by high accumulation mode integrated number concentrations. Night-time number concentration of particles (from 03:00 to 08:00 NST) are relatively low throughout the year (from 450 cm−3 during the monsoon season to 675 cm−3 during the pre-monsoon season), indicating the of high altitudes background level, as a result of downslope winds during this part of the day. However, it was found that these background concentrations are strongly influenced by the daytime concentrations, as they show the same seasonal variability. If nighttime concentrations were presumed to be representative of free troposphere (FT)/residual layer concentrations, they would be found to be two times higher than at other lower altitudes European sites, such as the Jungfraujoch. However, BL intrusions might contaminate the free troposphere/residual layer even at this altitude, especially during regional air masses influence. Night-time measurements were subsequently selected to study the FT composition according to different air masses, and the effect of long range transport to the station.
Highlights
Rapid economic growth in the Asian regions, in particular China and India, is causing strong air pollution problems that are not confined to urban and sub-urban areas, but involve a large fraction of the Asian continent, hosting over 4 billion people
The annual average number concentration measured over the two-year period at NCOP is 860±55 cm−3
The record is split between daytime (hereinafter defined from 10:00 to 18:00 Nepal Standard Time (NST)) and nighttime concentrations
Summary
Rapid economic growth in the Asian regions, in particular China and India, is causing strong air pollution problems that are not confined to urban and sub-urban areas, but involve a large fraction of the Asian continent, hosting over 4 billion people. Air pollution, in particular the particulate fraction, affects the atmospheric energy budget with significant impacts on regional climates and precipitation dynamics. This layer of particulate pollution that can be observed from satellites is often referred to as brown cloud. Considerable research investment has begun in Asia, bringing large-scale international and national regional experiments, such as INDOEX, (Indian Ocean Experiment), ACE-Asia (Aerosol-Cloud Experiment Asia) and ABC (Atmospheric Brown Cloud), studying precursor gases and aerosol. Affect the cloud-radiation feedback, with impacts on land-atmosphere interactions and precipitation in the Indo-Ganges Basin and the Himalayas
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