Kompalli, Sobhan Kumar ; Babu, S. Suresh ; Moorthy, K. Krishna ; Manoj, M.R. ; Kumar, N.V.P. Kiran ; Shaeb, K. Hareef Baba ; Joshi, Ashok Kumar (2014) Aerosol black carbon characteristics over Central India: Temporal variation and its dependence on mixed layer height Atmospheric Research, 147-14 . pp. 27-37. ISSN 0169-8095
Full text not available from this repository.
Official URL: http://doi.org/10.1016/j.atmosres.2014.04.015
Related URL: http://dx.doi.org/10.1016/j.atmosres.2014.04.015
Abstract
In a first of its kind study over the Indian region, concurrent and extensive measurements of black carbon (BC) concentration and atmospheric boundary layer parameters are used to quantify the role of atmospheric boundary layer in producing temporal changes in BC. During this study, 18 months (2011–12) data of continuous measurements of BC aerosols, made over a semi-urban location, Nagpur, in Central India are used along with concurrent measurements of vertical profiles of atmospheric thermodynamics, made using weekly ascents of GPS aided Radiosonde for a period of 1 year. From the balloon data, mixed layer heights and ventilation coefficients are estimated, and the monthly and seasonal changes in BC mass concentration are examined in the light of the boundary layer changes. Seasonally, the BC mass concentration was highest (~ 4573 ± 1293 ng m− 3) in winter (December–February), and lowest (~ 1588 ± 897 ng m− 3) in monsoon (June–September), while remained moderate (~ 3137 ± 1446 ng m− 3) in pre-monsoon (March–May), and post-monsoon (~ 3634 ± 813 ng m− 3) (October–November) seasons. During the dry seasons, when the rainfall is scanty or insignificantly small, the seasonal variations in BC concentrations have a strong inverse relationship with mixed layer height and ventilation coefficient. However, the lowest BC concentrations do not occur during the season when the mixed layer height (MLH) is highest or the ventilation coefficient is the highest; rather it occurs when the rainfall is strong (during summer monsoon season) and airmass changes to primarily of marine origin.
Item Type: | Article |
---|---|
Source: | Copyright of this article belongs to Elsevier Science. |
ID Code: | 125303 |
Deposited On: | 03 Feb 2022 06:01 |
Last Modified: | 03 Feb 2022 06:01 |
Repository Staff Only: item control page