Air flow and dry deposition of non-sea salt sulfate in polar firn: Paleoclimatic implications

Atmospheric Environment. Part A. General Topics Pub Date : 1993-12-01 DOI:10.1016/0960-1686(93)90327-U

J. Cunningham, E.D. Waddington

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引用次数: 80

Abstract

Non-sea salt sulfate aerosol (NSS) is an important factor for the Earth's albedo because it backscatters solar radiation and is the major cloud condensation nucleus over oceans. At Vostok, Antarctica, NSS concentration shows an increase in glacial period ice of 20–46% that cannot be attributed to changes in accumulation rate. The additional NSS may be due to enhanced dry deposition of NSS by topographic windpumping during the windy glacial periods. We model the volume flux of air into snow due to barometric pressure changes and air flow over surface microrelief. The Gormley-Kennedy equation approximately describes how aerosols advected into the snow pack are removed from the air by diffusion to the snow matrix. Barometric pressure and wind speed data from several polar sites have been used to quantify the vertical volume flux of air and mass flux of NSS. Model results indicate that air flow over small sastrugi, wind carved snow dunes commonly found on ice caps, is the dominant dry deposition mechanism for NSS. Paleo wind speed and surface roughness can significantly influence the aerosol record in ice cores.

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极地沉积物中非海盐硫酸盐的气流和干沉积:古气候意义

非海盐硫酸盐气溶胶(NSS)是地球反照率的一个重要因素，因为它对太阳辐射进行反向散射，是海洋上主要的云凝结核。在南极Vostok, NSS浓度显示冰期冰增加了20-46%，这不能归因于积累速率的变化。额外的NSS可能是由于在多风的冰期，地形风抽使NSS干沉积增强。我们模拟了由于大气压力变化和地表微地形上的空气流动而进入雪中的空气体积通量。Gormley-Kennedy方程大致描述了平流到积雪中的气溶胶如何通过扩散到雪基质中而从空气中移除。几个极地站点的气压和风速数据被用来量化NSS的空气垂直体积通量和质量通量。模型结果表明，在冰帽上常见的风雕沙丘上的气流是NSS的主要干沉积机制。古风速和地表粗糙度对冰芯气溶胶记录有显著影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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