Entropic Mixing of Ring/Linear Polymer Blends

IF 4.7 Q1 POLYMER SCIENCE ACS polymers Au Pub Date : 2022-11-28 DOI:10.1021/acspolymersau.2c00050
Gary S. Grest*, Ting Ge, Steven J. Plimpton, Michael Rubinstein and Thomas C. O’Connor*, 
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引用次数: 6

Abstract

The topological constraints of nonconcatenated ring polymers force them to form compact loopy globular conformations with much lower entropy than unconstrained ideal rings. The closed-loop structure of ring polymers also enables them to be threaded by linear polymers in ring/linear blends, resulting in less compact ring conformations with higher entropy. This conformational entropy increase promotes mixing rings with linear polymers. Here, using molecular dynamics simulations for bead-spring chains, ring/linear blends are shown to be significantly more miscible than linear/linear blends and that there is an entropic mixing, negative χ, for ring/linear blends compared to linear/linear and ring/ring blends. In analogy with small angle neutron scattering, the static structure function S(q) is measured, and the resulting data are fit to the random phase approximation model to determine χ. In the limit that the two components are the same, χ = 0 for the linear/linear and ring/ring blends as expected, while χ < 0 for the ring/linear blends. With increasing chain stiffness, χ for the ring/linear blends becomes more negative, varying reciprocally with the number of monomers between entanglements. Ring/linear blends are also shown to be more miscible than either ring/ring or linear/linear blends and stay in single phase for a wider range of increasing repulsion between the two components.

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环状/线型聚合物共混物的熵混合
非连接环聚合物的拓扑约束迫使它们形成紧凑的环状球状构象,其熵比无约束理想环低得多。环聚合物的闭环结构也使它们能够被环/线性混合物中的线性聚合物穿过,从而产生具有更高熵的不太紧凑的环构象。这种构象熵的增加促进了环与线性聚合物的混合。在这里,使用珠弹簧链的分子动力学模拟,环/线性共混物显示出比线性/线性共混更易混溶,并且与线性/线性和环/环共混物相比,环/线型共混物存在熵混合,负χ。与小角度中子散射类似,测量了静态结构函数S(q),并将所得数据拟合到随机相位近似模型中,以确定χ。在两种组分相同的极限下,线性/线性和环/环共混物的χ=0为预期值,而χ<;0表示环形/线性混合。随着链刚度的增加,环/线性共混物的χ变得更负,随着缠结之间单体数量的倒数变化。环/线性混合物也显示出比环/环或线性/线性混合物更易混溶,并且在两种组分之间更宽范围的增加的排斥作用下保持单相。
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