Immersion ice nucleation of atmospherically relevant lipid particles†

IF 2.8 Q3 ENVIRONMENTAL SCIENCES Environmental science: atmospheres Pub Date : 2024-09-25 DOI:10.1039/D4EA00066H
Lincoln Mehndiratta, Audrey E. Lyp, Jonathan H. Slade and Vicki H. Grassian
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Abstract

Ice nucleating particles (INPs) play a crucial role in freezing water droplets by acting as heterogeneous ice nuclei, influencing cloud phase state and climate dynamics. INPs from marine aerosol particles are particularly relevant. Saturated fatty alcohols and acids have been identified in sea spray aerosols (SSA). In this study, we employ a micro-Raman spectrometer integrated with an environmental cell to control relative humidity and temperature and measure the ice nucleation activity of individual lipid particles, including fatty alcohols and fatty acids of varying chain lengths. For fatty acids, we observe little IN activity for these lipid particles as they freeze close to the temperature found for homogeneous freezing. For fatty alcohols, we demonstrate that freezing temperatures depend on the carbon chain length, with longer chains leading to warmer ice nucleating temperatures. Although this result qualitatively agrees with existing literature, we observe that the ice nucleating temperatures of these lipid particles differ from the freezing temperatures measured for fatty alcohol monolayers at the air/water interface for large water droplets. To better understand these differences, we further investigate the effects of droplet size as well as phase state by theoretically determining the wet viscosity on freezing. Our results, taken together, suggest that for fatty alcohol particles, freezing occurs at the lipid particle/water interface. Overall, our findings highlight the influence of lipid chain length, droplet size, and phase state on ice nucleation for lipid particles.

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与大气相关的脂质颗粒的浸入式冰核形成†。
冰核粒子(INPs)通过充当异质冰核在水滴冻结过程中发挥着至关重要的作用,影响着云相状态和气候动力学。来自海洋气溶胶颗粒的 INPs 尤其具有相关性。在海雾气溶胶(SSA)中发现了饱和脂肪醇和酸。在这项研究中,我们利用微拉曼光谱仪与环境电池集成来控制相对湿度和温度,并测量单个脂质颗粒的冰核活性,包括不同链长的脂肪醇和脂肪酸。对于脂肪酸,我们观察到这些脂质微粒几乎没有 IN 活性,因为它们的冻结温度接近均匀冻结时的温度。对于脂肪醇,我们证明冻结温度取决于碳链长度,碳链越长,冰核温度越高。虽然这一结果与现有文献的定性结果一致,但我们观察到这些脂质颗粒的冰核温度与脂肪醇单层在大水滴的空气/水界面上测得的冻结温度不同。为了更好地理解这些差异,我们通过理论测定冻结时的湿粘度,进一步研究了水滴大小和相态的影响。我们的研究结果表明,对于脂肪醇颗粒来说,冻结发生在脂质颗粒/水的界面上。总之,我们的研究结果凸显了脂质链长、液滴大小和相态对脂质颗粒冰核形成的影响。
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