稀释的多价盐诱导的聚电解质的回流凝结:静电胶子效应的作用。

IF 5.5 2区 化学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY
Biomacromolecules Pub Date : 2024-11-11 Epub Date: 2024-10-21 DOI:10.1021/acs.biomac.4c01037
Huaisong Yong
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引用次数: 0

摘要

我们探讨了多价盐引发的聚电解质的重入凝结,其相变机制仍存在争议。我们提出了一种研究重入凝结的理论,它将静电效应分为两部分:由于离子单体共享多价离子而产生的短程静电胶子效应和来自所有离子的长程静电相关效应。该理论认为,静电胶子效应控制着重入凝结,需要最小的耦合能来启动相变。这就解释了为什么具有选择性多价的稀盐会引发多电解质相变。该理论还揭示了多价离子对离子单体的强吸附作用会导致低盐浓度同时诱发塌缩和重入转变。此外,我们还强调了不带电的聚电解质分子与水的不相容性如何影响聚电解质相行为。如果与生物多电解质结合的多价离子发挥了重要作用,那么所获得的结果将有助于理解生物相分离。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Reentrant Condensation of Polyelectrolytes Induced by Diluted Multivalent Salts: The Role of Electrostatic Gluonic Effects.

We explore the reentrant condensation of polyelectrolytes triggered by multivalent salts, whose phase-transition mechanism remains under debate. We propose a theory to study the reentrant condensation, which separates the electrostatic effect into two parts: a short-range electrostatic gluonic effect because of sharing of multivalent ions by ionic monomers and a long-range electrostatic correlation effect from all ions. The theory suggests that the electrostatic gluonic effect governs reentrant condensation, requiring a minimum coupling energy to initiate the phase transition. This explains why diluted salts with selective multivalency trigger a polyelectrolyte phase transition. The theory also uncovers that strong adsorption of multivalent ions onto ionic monomers causes low-salt concentrations to induce both collapse and reentry transitions. Additionally, we highlight how the incompatibility of uncharged polyelectrolyte moieties with water affects the polyelectrolyte phase behaviors. The obtained results will contribute to the understanding of biological phase separations if multivalent ions bound to biopolyelectrolytes play an essential role.

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来源期刊
Biomacromolecules
Biomacromolecules 化学-高分子科学
CiteScore
10.60
自引率
4.80%
发文量
417
审稿时长
1.6 months
期刊介绍: Biomacromolecules is a leading forum for the dissemination of cutting-edge research at the interface of polymer science and biology. Submissions to Biomacromolecules should contain strong elements of innovation in terms of macromolecular design, synthesis and characterization, or in the application of polymer materials to biology and medicine. Topics covered by Biomacromolecules include, but are not exclusively limited to: sustainable polymers, polymers based on natural and renewable resources, degradable polymers, polymer conjugates, polymeric drugs, polymers in biocatalysis, biomacromolecular assembly, biomimetic polymers, polymer-biomineral hybrids, biomimetic-polymer processing, polymer recycling, bioactive polymer surfaces, original polymer design for biomedical applications such as immunotherapy, drug delivery, gene delivery, antimicrobial applications, diagnostic imaging and biosensing, polymers in tissue engineering and regenerative medicine, polymeric scaffolds and hydrogels for cell culture and delivery.
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