Effect of Counterion Size on Knotted Polyelectrolyte Conformations

IF 2.8 2区 化学 Q3 CHEMISTRY, PHYSICAL
Andrea Tagliabue*, Cristian Micheletti and Massimo Mella*, 
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Abstract

Using Langevin dynamics simulations and a coarse-grained primitive model of electrolytes, we show that the behavior of knotted circular strong polyelectrolytes (PEs) in diluted aqueous solution is largely affected by the diameter of the counterions (CIs), σCI. Indeed, we observe that both gyration radius and knot length vary nonmonotonically with σCI, with both small and bulky CIs favoring knot localization, while medium-sized ones promote delocalized knots. We also show that the conformational change from delocalized to tight knots occurs via the progressive coalescence of the knot’s essential crossings. The emerging conformers correspond to the minima of the free energy landscape profiled as a function of the knot length or PE size. We demonstrate that different conformational states can coexist, the transition between them appearing first-order-like and controlled by the enthalpic and entropic trade-off of the amount of CIs condensed on the PE. Such balance can be further altered by varying CI concentrations, thus providing an additional and more convenient tuning parameter for the system properties. Our results lay the foundation for achieving broader and more precise external adjustability of knotted PE size and shape by choosing the nature of its CIs. Thus, they offer new intriguing possibilities for designing novel PE-based materials that are capable of responding to changes in ionic solution properties.

Abstract Image

Abstract Image

反离子尺寸对打结聚电解质构型的影响
利用朗格文动力学模拟和电解质粗粒度原始模型,我们发现在稀释水溶液中,结环强聚电解质(PEs)的行为在很大程度上受到反离子(CIs)直径 σCI 的影响。事实上,我们观察到回旋半径和结的长度都随着 σCI 的变化而非单调变化,小而大的 CI 有利于结的定位,而中等大小的 CI 则促进结的非定位。我们还证明,从分散结到紧密结的构象变化是通过结的基本交叉点逐渐凝聚而发生的。新出现的构象与自由能谱的最小值相对应,自由能谱是结的长度或 PE 大小的函数。我们证明,不同的构象状态可以共存,它们之间的转变是一阶式的,并受到凝结在 PE 上的 CIs 数量的焓和熵权衡的控制。这种平衡可以通过改变 CI 浓度来进一步改变,从而为系统特性提供了一个额外的、更方便的调节参数。我们的研究结果为通过选择 CIs 的性质来实现更广泛、更精确的结状聚乙烯尺寸和形状的外部可调性奠定了基础。因此,它们为设计能够应对离子溶液特性变化的新型聚乙烯基材料提供了新的令人感兴趣的可能性。
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来源期刊
CiteScore
5.80
自引率
9.10%
发文量
965
审稿时长
1.6 months
期刊介绍: An essential criterion for acceptance of research articles in the journal is that they provide new physical insight. Please refer to the New Physical Insights virtual issue on what constitutes new physical insight. Manuscripts that are essentially reporting data or applications of data are, in general, not suitable for publication in JPC B.
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