A new optical freezing array for the study of heterogeneous ice nucleation in microliter-sized droplets is introduced, tested and applied to the study of immersion freezing in aqueous Snomax suspensions. In the Bielefeld Ice Nucleation ARraY (BINARY) ice nucleation can be studied simultaneously in 36 droplets at temperatures down to −40 °C (233 K) and at cooling rates between 0.1 and 10 K min. The droplets are separated from each other in individual compartments, thus preventing a Wegener–Bergeron–Findeisen type water vapor transfer between droplets as well as avoiding the seeding of neighboring droplets by formation and surface growth of frost halos. Analysis of freezing and melting occurs via an automated real-time image analysis of the optical brightness of each individual droplet. As an application ice nucleation in water droplets containing Snomax at concentrations from 1 ng mL to 1 mg mL was investigated. Using different cooling rates, a small time dependence of ice nucleation induced by two different classes of ice nucleators (INs) contained in Snomax was detected and the corresponding heterogeneous ice nucleation rate coefficient was quantified. The observed time dependence is smaller than those of other types of INs reported in the literature, suggesting that the BINARY setup is suitable for quantifying time dependence for most other INs of atmospheric interest, making it a useful tool for future investigations.
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机译:介绍了一种用于研究微升大小的液滴中异质冰核化的新型光学冷冻阵列,并将其应用于浸没冷冻在Snomax水性悬浮液中的研究。在比勒费尔德冰核形成研究中,可以在温度低至−40°C(233 K)且冷却速率介于0.1至10 K min之间的36个液滴中同时研究冰成核作用。液滴在单独的隔室中彼此分离,从而防止了Wegener-Bergeron-Findeisen型液滴之间的水蒸气转移,并避免了由于霜晕的形成和表面生长而导致相邻液滴的播种。冻结和融化的分析是通过对每个小滴的光学亮度进行自动实时图像分析来进行的。作为应用,研究了浓度为1 ng mL至1 mg mL的含Snomax水滴的冰核化作用。使用不同的冷却速率,检测到由Snomax中包含的两种不同类别的冰核形成器(IN)引起的冰核形成的时间依赖性小,并量化了相应的非均质冰核形成率系数。观测到的时间依赖性小于文献中报道的其他类型的IN的时间依赖性,这表明BINARY设置适合于量化大多数其他与大气有关的IN的时间依赖性,使其成为将来研究的有用工具。
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