Abstract
Abstract. The possible minimal range of reduction in snow surface albedo due to dry deposition of black carbon (BC) in the pre-monsoon period (March–May) was estimated as a lower bound together with the estimation of its accuracy, based on atmospheric observations at the Nepal Climate Observatory – Pyramid (NCO-P) sited at 5079 m a.s.l. in the Himalayan region. A total BC deposition rate was estimated as 2.89 μg m−2 day−1 providing a total deposition of 266 μg m−2 for March–May at the site, based on a calculation with a minimal deposition velocity of 1.0×10−4 m s−1 with atmospheric data of equivalent BC concentration. Main BC size at NCO-P site was determined as 103.1–669.8 nm by correlation analyses between equivalent BC concentration and particulate size distributions in the atmosphere. The BC deposition from the size distribution data was also estimated. It was found that 8.7% of the estimated dry deposition corresponds to the estimated BC deposition from equivalent BC concentration data. If all the BC is deposited uniformly on the top 2-cm pure snow, the corresponding BC concentration is 26.0–68.2 μg kg−1, assuming snow density variations of 195–512 kg m−3 of Yala Glacier close to NCO-P site. Such a concentration of BC in snow could result in 2.0–5.2% albedo reductions. By assuming these albedo reductions continue throughout the year, and then applying simple numerical experiments with a glacier mass balance model, we estimated reductions would lead to runoff increases of 70–204 mm of water. This runoff is the equivalent of 11.6–33.9% of the annual discharge of a typical Tibetan glacier. Our estimates of BC concentration in snow surface for pre-monsoon season is comparable to those at similar altitudes in the Himalayan region, where glaciers and perpetual snow regions begin, in the vicinity of NCO-P. Our estimates from only BC are likely to represent a lower bound for snow albedo reductions, because we used a fixed slower deposition velocity. In addition, we excluded the effects of atmospheric wind and turbulence, snow aging, dust deposition, and snow albedo feedbacks. This preliminary study represents the first investigation of BC deposition and related albedo on snow, using atmospheric aerosol data observed at the southern slope in the Himalayas.
Highlights
Atmospheric aerosol has a significant direct and indirect impact on the earth’s climate (IPCC, 2007)
The aim of this study is to provide a preliminary lower bound estimate of BC deposition (BCD) and BC concentrations (BCC) on and in the snow surface on the Himalayan region during the pre-monsoon period, based on Nepal Climate Observatory – Pyramid (NCO-P) atmospheric observations recorded in March–May 2006
To ascertain the typical size range of Black carbon (BC), the correlation analyses between counts in OPC and Scanning Mobility Particle Sizer (SMPS) bins and equivalent BC concentration (eqBCC) in the atmosphere were carried out in time series data (Fig. 2a and b)
Summary
Atmospheric aerosol has a significant direct and indirect impact on the earth’s climate (IPCC, 2007). Lau et al (2006, 2008), proposed the so-called Elevated Heat Pump (EHP) effect, whereby heating of the atmosphere by elevated absorbing aerosols strengthens local atmospheric circulation, leading to a northward shift of the monsoon rain belt, resulting in increased rainfall in northern Indian and the foothills of the Himalayas in the late boreal spring and early summer season. The effect increases heating of the snow and ice surface, accelerating melting, shortening snow duration, altering mass balance and causing the retreat of mountain glaciers. These physical activities change the amount of available water resource in the region (e.g., Hansen and Nazarenko, 2004; IPCC, 2007; Flanner et al, 2007, 2009)
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