# Oil drop deposition on solid surfaces in mixed polymer-surfactant   solutions in relation to hair- and skin-care applications

**Authors:** Rumyana D. Stanimirova, Peter A. Kralchevsky, Krassimir D. Danov, Hui, Xu, Yee Wei Ung, Jordan T. Petkov

arXiv: 1905.10997 · 2020-02-26

## TL;DR

This study introduces a new method to analyze oil drop adhesion on solid surfaces from mixed surfactant-polymer solutions, revealing how formulation components influence deposition relevant to hair and skin care.

## Contribution

A novel pressed drop method (PDM) is proposed to quantify oil drop adhesion thresholds, aiding formulation optimization in personal care products.

## Key findings

- CAPB suppresses oil-drop deposition as its fraction increases
- SME facilitates easier drop adhesion than SLES
- NaCl enhances, CMEA suppresses drop deposition

## Abstract

The deposition of oil drops on solid substrates from mixed solutions of surfactants and cationic polymer is investigated. The used anionic surfactants are sodium laurylethersulfate (SLES) and sulfonated methyl esters (SME); the zwitterionic surfactant is cocamidopropyl betaine (CAPB). A new method, called the pressed drop method (PDM), was proposed to study the drop adhesion to substrates of different hydrophobicity. The PDM allows one to detect the presence or absence of drop adhesion at different degrees of dilution of the initial solution and, thus, to determine the threshold concentration of drop adhesion. The results show that the increase of the fraction of CAPB in the mixture with the anionic surfactant suppresses the oil-drop deposition; SME provides easier drop adhesion than SLES; the addition of NaCl enhances, whereas coco-fatty-acid-monoethanolamide (CMEA) suppresses the drop deposition; no drop adhesion is observed in the absence of polymer. The drop-to-substrate adhesion is interpreted in terms of the acting surface forces: polymer bridging attraction; hydrophobic attraction between segments of adsorbed polymer brushes and electrostatic forces. From viewpoint of applications, the PDM experiments enable one to compare the performance of various components in personal care formulations and to optimize their composition with respect to the oil-drop deposition.

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Source: https://tomesphere.com/paper/1905.10997