Multiscale coarse-grained (CG) modeling of soft materials, such as polymers, is currently an art form because CG models normally have significantly altered dynamics and thermodynamic properties compared to their atomistic counterparts. We address this problem by exploiting concepts derived from the generalized entropy theory (GET), emphasizing the central role of configurational entropy ssubc/sub in the dynamics of complex fluids. Our energy renormalization (ER) method involves varying the cohesive interaction strength in the CG models in such a way that dynamic properties related to ssubc/sub are preserved. We test this ER method by applying it to coarse-graining polymer melts (i.e., polybutadiene, polystyrene, and polycarbonate), representing polymer materials having a relatively low, intermediate, and high degree of glass “fragility”. We find that the ER method allows the dynamics of the atomistic polymer models to be faithfully described to a good approximation by CG models over a wide temperature range.
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机译:目前,对软材料(例如聚合物)进行多尺度粗粒度(CG)建模是一种艺术形式,因为与原子对应模型相比,CG模型通常具有显着改变的动力学和热力学特性。我们通过利用从广义熵理论(GET)衍生的概念来解决此问题,强调构型熵s c 在复杂流体动力学中的核心作用。我们的能量重整化(ER)方法涉及改变CG模型中的内聚相互作用强度,从而保留与s c 有关的动态特性。我们通过将其应用于粗粒聚合物熔体(即聚丁二烯,聚苯乙烯和聚碳酸酯)来测试该ER方法,该方法代表了具有相对较低,中度和高度的玻璃“脆性”的聚合物材料。我们发现,ER方法可以在较宽的温度范围内忠实地描述原子聚合物模型的动力学,并通过CG模型很好地近似。
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