Mapping self-avoiding walk on obstacle-ridden lattice onto chelation of heavy metal ions: Monte Carlo study

arXiv - PHYS - Soft Condensed Matter Pub Date : 2024-09-17 DOI:arxiv-2409.10974

V. Blavatska, Ja. Ilnytskyi, E. Lähderanta

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Abstract

Self-avoiding walk (SAW) represents linear polymer chain on a large scale, neglecting its chemical details and emphasizing the role of its conformational statistics. The role of the latter is important in formation of agglomerates and complexes involving polymers and organic or inorganic particles, such as polymer-stabilized colloidal suspensions, microemulsions, or micellar solutions. When such particles can be adsorbed on a polymer of considerably larger dimensions than themselves, this setup may represent chelation of heavy metal ions by polymeric chelants. We consider the SAW of the length $N$ on a cubic lattice ridden by randomly distributed obstacles of the concentration $p$ interpreted as ions. The SAW monomers can bind to the obstacles with variable binding energy $\varepsilon$ mimicking formation of the chelation bond. Pruned-enriched Rosenbluth method (PERM) Monte Carlo (MC) algorithm is applied to simulate system behaviour. We focus on several relevant properties related to the chelation efficiency and strength, as functions of the variables set $\{p,N,\varepsilon\}$. The results are interpreted in terms of conformational freedom, excluded volume effects and loop formation for the SAW, and the tendencies being predicted are in agreement with some experimental data.

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绘制重金属离子螯合的障碍晶格自避让行走图：蒙特卡罗研究

自避让步行（SAW）是线性聚合物链的大尺度表示，忽略了其化学细节，强调了其构象特性的作用。后者在聚合物与有机或无机微粒（如聚合物稳定胶体悬浮液、微乳液或胶束溶液）形成团聚体和复合物的过程中发挥着重要作用。当这些微粒能够吸附在比自身尺寸大得多的聚合物上时，这种设置可能代表聚合物螯合剂对重金属离子的螯合作用。我们考虑的是立方晶格上长度为 $N$ 的声表面波，其上有被解释为离子的浓度为 $p$ 的随机分布的障碍物。SAW 单体能以可变的结合能 $\varepsilon$ 与障碍物结合，模拟螯合键的形成。我们重点研究了与螯合效率和强度有关的几个相关特性，它们是变量集${p,N,\varepsilon\}$的函数。我们从 SAW 的构象自由度、排除体积效应和环路形成等方面对结果进行了解释，所预测的趋势与一些实验数据一致。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Soft Condensed Matter

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