Evaporative phase separation in polymer microdroplets with confinement and internal flow

Q3 Materials Science JCIS open Pub Date : 2023-12-16 DOI:10.1016/j.jciso.2023.100101

Mukesh Kumar, Maheshwar Gopu, Senthan Pugalneelam Parameswaran, Prerak Joshi, Dileep Mampallil

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Abstract

Evaporation can drive initially homogeneous multiphase liquid systems out of equilibrium to induce liquid-liquid phase separation (LLPS). Here, we demonstrate evaporative LLPS in microfluidic-generated emulsion microdroplets of polymer mixtures. The evaporation produces distinct polymer phases within the microdroplets. Phase separation occurs even with polymer combinations that do not form distinct phases in sessile droplet evaporation. We attribute this aspect to evaporation-driven solutal Marangoni flows and the interface capture accumulating the nuclei at the apex where the evaporation rate is the maximum. A fast coalescence and growth of the accumulated polymer nuclei occurs inside the droplets, unlike the capillary-flow-induced spread-out of the nuclei along the contact line in sessile drops. Our method of evaporation of the droplet cluster may facilitate studying LLPS in volume-limited environments and have implications for understanding LLPS in biological systems.

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具有封闭性和内部流动性的聚合物微滴中的蒸发相分离

蒸发可使最初均相的多相液体系统失去平衡，从而诱发液-液相分离（LLPS）。在这里，我们展示了微流体产生的聚合物混合物乳液微滴中的蒸发 LLPS。蒸发在微液滴中产生了不同的聚合物相。即使是在无柄液滴蒸发过程中不会形成不同相的聚合物组合，也会发生相分离。我们将这方面的原因归结为蒸发驱动的溶质马兰戈尼流和界面捕获，在蒸发速率最大的顶点积累晶核。累积的聚合物晶核在液滴内部快速凝聚和生长，这与无柄液滴中由毛细管流引起的晶核沿接触线扩散不同。我们的液滴团蒸发方法可能有助于在体积受限的环境中研究 LLPS，并对了解生物系统中的 LLPS 有一定意义。

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