Black carbon concentration in the central Himalayas: Impact on glacier melt and potential source contribution

This study discusses year-long (October 2016&#8211;September 2017) observations of atmospheric black carbon (BC) mass concentration, its source and sector contributions using a chemical transport model at a high-altitude (28&#176;12'49.21"N, 85&#176;36'33.77"E, 4900 masl) site located near the Yala Glacier in the central Himalayas, Nepal. During a field campaign, fresh snow samples were collected from the surface of the Yala Glacier in May 2017, which were analysed for BC and water-insoluble organic carbon mass concentration in order to estimate the scavenging ratio and surface albedo reduction. The maximum BC mass concentration in the ambient atmosphere (0.73 &#956;g m-3) was recorded in the pre-monsoon season. The BC and water-insoluble organic carbon analysed from the snow samples were in the range of 96&#8211;542 ng g-1 and 152&#8211;827 ng g-1, respectively. The source apportionment study using the absorption &#197;ngstr&#246;m exponent from in situ observations indicated approximately 44% contribution of BC from biomass-burning sources and the remainder from fossil-fuel sources during the entire study period. The source contribution study, using model data sets, indicated ~14% contribution of BC from open-burning and ~77% from anthropogenic sources during the study period. Our analysis of regional contributions of BC indicated that the highest contribution was from both Nepal and India combined, followed by China, while the rest was distributed among the nearby countries. The surface snow albedo reduction, estimated by an online model &#8211; Snow, Ice, and Aerosol Radiation &#8211; was in the range of 0.8&#8211;3.8% during the pre-monsoon season. The glacier melt analysis suggested that BC contributed to approximately 28% of the total melting in the pre-monsoon season.&#160;

Download Full-text

Traffic Density-Related Black Carbon Distribution: Impact of Wind in a Basin Town

International Journal of Environmental Research and Public Health ◽

10.3390/ijerph18126490 ◽

2021 ◽

Vol 18 (12) ◽

pp. 6490

Author(s):

Borut Jereb ◽

Brigita Gajšek ◽

Gregor Šipek ◽

Špela Kovše ◽

Matevz Obrecht

Keyword(s):

Black Carbon ◽

Carbon Concentration ◽

Ground Level ◽

Traffic Density ◽

Carbon Distribution ◽

Wind Speeds ◽

Black Carbon Concentration ◽

Low Wind Speeds ◽

Temperature Inversions ◽

Carbon Concentrations

Black carbon is one of the riskiest particle matter pollutants that is harmful to human health. Although it has been increasingly investigated, factors that depend on black carbon distribution and concentration are still insufficiently researched. Variables, such as traffic density, wind speeds, and ground levels can lead to substantial variations of black carbon concentrations and potential exposure, which is even riskier for people living in less-airy sites. Therefore, this paper “fills the gaps” by studying black carbon distribution variations, concentrations, and oscillations, with special emphasis on traffic density and road segments, at multiple locations, in a small city located in a basin, with frequent temperature inversions and infrequent low wind speeds. As wind speed has a significant impact on black carbon concentration trends, it is critical to present how low wind speeds influence black carbon dispersion in a basin city, and how black carbon is dependent on traffic density. Our results revealed that when the wind reached speeds of 1 ms−1, black carbon concentrations actually increased. In lengthy wind periods, when wind speeds reached 2 or 3 ms−1, black carbon concentrations decreased during rush hour and in the time of severe winter biomass burning. By observing the results, it could be concluded that black carbon persists longer in higher altitudes than near ground level. Black carbon concentration oscillations were also seen as more pronounced on main roads with higher traffic density. The more the traffic decreases and becomes steady, the more black carbon concentrations oscillate.

Download Full-text

Comparing Seasonal Diffences of Black Carbon in Tibetan Plateau transported from South Asia using WRF-Chem

10.5194/egusphere-egu21-6825 ◽

2021 ◽

Author(s):

Shuoqiu Wu ◽

Xiaoyan Ma

Keyword(s):

South Asia ◽

Black Carbon ◽

Carbon Concentration ◽

Wet Deposition ◽

Emission Inventory ◽

Tibet Plateau ◽

Black Carbon Concentration ◽

Different Seasons ◽

Qinghai Tibet Plateau ◽

The Vertical Distribution

The melting of glaciers and snow on the Qinghai-Tibet Plateau, known as the Earth&#8217;s &#8220;Third Pole&#8221; and &#8220;World Water Tower&#8221;, is source of fresh water for hundreds of millions of people in South Asia, Southeast Asia, and East Asia, but it is now suffering from an unprecedented crisis. The black carbon deposited on the surface of the glacier will reduce the snow albedo and absorb more solar radiation, leading to accelerated melting of ice and snow.Previous studies have shown that black carbon from South Asia is one of the main sources of the Qinghai-Tibet Plateau, and the transportation of black carbon to the Qinghai-Tibet Plateau presents obviously seasonal differences.However, the transport of black carbon from South Asia to the Qinghai-Tibet Plateau in different seasons shows a completely opposite trend to wind field conditions.This study uses the WRF-Chem model to study the transmission mechanism of South Asian black carbon to the Tibetan Plateau in April (pre-monsoon), July (summer monsoon) and December (winter monsoon).MIX emission inventory and Peking University's global black carbon emission inventory (PKU-BC) were involved to analyze the seasonal distribution of black carbon concentration, dry and wet deposition in the Qinghai-Tibet Plateau and South Asia, and the distribution of BC concentration and wind field at different altitudes.Combined with the vertical distribution of BC concentration across the Himalayas, the transport mechanism of black carbon in South Asia&#160;to Qinghai-Tibet Plateau in different seasons is studied.In the selected three months, December had the highest surface black carbon concentration in South Asia and the Qinghai-Tibet Plateau, while&#160;July had the lowest black carbon concentration; Mainly because&#160;of&#160;the large amount of wet deposition of black carbon brought about by the heavy precipitation in South Asia in July;According to the vertical distribution of black carbon,black carbon can climb up the hillside and eventually reach the southern slope of the Qinghai-Tibet Plateau&#160;in April. In July, black carbon is mainly distributed below 3km. In December, black carbon can be uplifted to 4-5km, and finally transported into Qinghai-Tibet Plateau.

Download Full-text