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研究领域化学科学物理化学体和表面化学
在矿物表面上Zwitterionic表面活性剂吸附的机制建模:三步异温与菌诱导的脱吸

在矿物表面上Zwitterionic表面活性剂吸附的机制建模:三步异温与菌诱导的脱吸

Pablo A Godoy ¹, Luis Maqueira ², Aurora Pérez-Gramatges ^1,2

Pablo A Godoy ¹, Luis Maqueira ², Aurora Pérez-Gramatges ^1,2

¹Department of Chemistry, Pontifical Catholic University of Rio de Janeiro (PUC-Rio), Rio de Janeiro 22451-900, Brazil.
²Laboratory of Physical-Chemistry of Surfactants (LASURF), Pontifical Catholic University of Rio de Janeiro (PUC-Rio), Rio de Janeiro 22451-900, Brazil.

⁰Department of Chemistry, Pontifical Catholic University of Rio de Janeiro (PUC-Rio), Rio de Janeiro 22451-900, Brazil.

Langmuir : the Acs Journal of Surfaces and Colloids +

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2025年八月26日

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在PubMed上查看摘要

概括

此摘要是机器生成的。

一个新的三步表面活性剂吸附模型解释了微粒触发的脱吸,改善了矿物吸附预测. 该模型准确地描述了砂岩和石灰岩上的可卡米多贝他因吸附,并提供了关于多孔介质中表面活性物损失的见解.

科学领域

表面化学
体科学
材料科学

背景情况

传统的隔热模型未能捕获异常的表面活性物后的形成行为.
在吸附研究中,微粒诱导的从矿物表面脱落是一个关键的,但尚未解决的现象.

研究的目的

引入一种新型的三步吸附模型,其中包括微粒触发的脱吸.
通过对砂岩和石灰岩的可卡米多贝他因实验数据验证模型.
研究电气双层特性对表面活性剂吸附的影响.

主要方法

开发了一个三步吸附模型,扩展了经典的两步理论.
在临界度激活的菌触发脱吸机制.
使用表面复杂模型 (SCM) 来分析电气双层特性.

主要成果

该三步模型准确地预测了砂岩 (2.15 mg/m2) 和石灰岩 (1.85 mg/m2) 上的可卡米多普贝他因吸附.
由于有利的头组亲和力和包装,砂岩具有较高的表面活性吸附.
模型与各种表面活性剂的实验和文献数据有很好的一致性.

结论

拟议的模型准确地描述了表面活性剂的吸附,包括由小粒诱导的聚合物脱吸.
当表面活性剂头组和矿物表面具有相同的电荷特征时,吸附最大值与菌诱导的脱吸有关.
SCM模拟表明岩石表面的电荷异质性可以减轻吸附效应,有助于预测长期的表面活性物质损失.

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