Influence of supersaturation on the concentration of ice nucleating particles

F. Belosi, M. Piazza, A. Nicosia, G. Santachiara
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引用次数: 2

Abstract

Abstract There is a consensus on the increase in ice nucleating particles (INP) concentration from subsaturated to supersaturated water conditions typically associated with clouds (1 ÷ 2%). However, it is important to evaluate the INP concentration trend when water supersaturation further increases, as supercooled clouds contain pockets of high water vapor supersaturation. Three laboratory dry-generated aerosols, two biological (microcrystalline and fibrous cellulose) and one mineral (Arizona test dust), and a field aerosol, sampled on filters, were investigated. Atmospheric aerosol (PM1 and PM10 fractions) was sampled at Capo Granitola (CG, coastal site in Sicily) and the National Research Council (CNR) research area in Bologna (urban background site). The dynamic filter processing chamber (DFPC) was used to explore the ice nucleation of the sampled aerosol in the deposition and condensation freezing modes. Experiments were performed from water subsaturated conditions (water saturation ratio Sw = 0.94) to Sw = 1.1, at T = −22 °C. At CG we considered separately events with a prevalent contribution of marine aerosol, and those showing a contribution of both marine and continental aerosols. An increase in INP concentration, the aerosol activated fraction (AF) and ice nucleation active surface site density (ns) from water subsaturated conditions to Sw = 1.02 was measured in both laboratory and field campaigns. This increase is due to the transition from deposition nucleation to condensation freezing. The highest increases in AF and ns from Sw = 1.02 to Sw = 1.1 were obtained for urban and mixed aerosol and the lowest for marine aerosol. Samplings performed in Bologna showed a high increase in the average INP concentration from PM1 to PM10. Our results show the importance of performing measurements of ice nucleation efficiency for continental aerosol even at supersaturation values higher than those typically associated with clouds, and also considering the contribution of coarse aerosol particles.
过饱和对冰成核颗粒浓度的影响
关于冰成核粒子(INP)浓度从亚饱和到过饱和的增加(1 ÷ 2%)通常与云有关,这是一个共识。然而,当水的过饱和进一步增加时,评估INP浓度的趋势是很重要的,因为过冷云中含有高水蒸气过饱和的小袋。研究了三种实验室干燥产生的气溶胶,两种生物(微晶和纤维纤维素)和一种矿物(亚利桑那试验粉尘),以及一种现场气溶胶,取样于过滤器上。在Capo Granitola(西西里岛沿海站点)和博洛尼亚国家研究委员会(CNR)研究区(城市背景站点)取样大气气溶胶(PM1和PM10组分)。采用动态过滤处理室(DFPC)对采样气溶胶在沉降和凝结冻结模式下的冰核进行了研究。实验从水的亚饱和状态(水饱和比Sw = 0.94)到Sw = 1.1,温度为- 22°C。在气候变化大会上,我们分别考虑了主要由海洋气溶胶贡献的事件,以及同时由海洋和大陆气溶胶贡献的事件。在实验室和野外试验中测量了INP浓度、气溶胶活性组分(AF)和冰核活性表面位点密度(ns)从水亚饱和状态到Sw = 1.02的增加。这种增加是由于从沉积成核到凝结冻结的转变。城市气溶胶和混合气溶胶的AF和ns从Sw = 1.02增加到Sw = 1.1最大,海洋气溶胶最小。在博洛尼亚进行的采样显示,从PM1到PM10的平均INP浓度大幅增加。我们的研究结果表明,即使在比通常与云相关的过饱和值更高的情况下,对大陆气溶胶进行冰成核效率测量的重要性,并考虑到粗气溶胶颗粒的贡献。
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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