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2015 | Buch

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Smart Wormlike Micelles

Design, Characteristics and Applications

verfasst von: Yujun Feng, Zonglin Chu, Cécile A. Dreiss

Verlag: Springer Berlin Heidelberg

Buchreihe : SpringerBriefs in Molecular Science

Enthalten in: Springer Professional "Wirtschaft+Technik" , Springer Professional "Technik"

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Über dieses Buch

This Brief provides an up-to-date overview of smart surfactants and describes a broad spectrum of triggers that induce the formation of wormlike micelles or reversibly tune the morphology of surfactant aggregates from wormlike micelles to another state, or vice versa. Combining the fields of chemistry, physics, polymer science, and nanotechnology, its primary focus is on the design, formulation, and processing of intelligent viscoelastic surfactant solutions, covering the scientific principles governing responsiveness to one or more particular triggers, down to the end-use-driven functions. The first chapter explains why and how surfactants self-assemble into viscoelastic wormlike micellar solutions reminiscent of polymer solutions, while the following chapters show how the response to a given trigger translates into macroscopic rheological changes, including temperature, light, pH, CO2, redox, hydrocarbon, etc. The last chapter demonstrates the applications of these viscoelastic assemblies in oil and gas production, drag reduction, biomaterials, cleaning processes, electrorheological and photorheological fluids. Comments and perspectives are provided at the end to conclude this Brief.

This Brief is aimed at chemists, physicists, chemical engineers and nano-scientists who are involved in self-assemblies and applications of surfactants, as well as graduates in physical chemistry.

Yujun Feng, Ph.D., is a professor at the State Key Laboratory of Polymer Materials Engineering, Polymer Research Institute of Sichuan University, Chengdu, Sichuan Province, P. R. China.
Zonglin Chu, Ph.D., is a post-doctoral fellow working at the Physical Chemistry Institute, University of Zürich, Switzerland.
Cécile A. Dreiss, Ph.D., is a senior lecturer at the Institute of Pharmaceutical Science, King’s College London, UK.

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Inhaltsverzeichnis

Frontmatter

Chapter 1. Basic Properties of Wormlike Micelles

Abstract

Surfactants are probably the most fascinating family of small amphiphilic molecules, not only because of their everyday use in our life, but also because of their attractive macroscopic properties—all of which result from their versatile self-assembly properties and microstructures. In this chapter, we recall the basic properties of surfactant assemblies, in particular, the classical “critical packing parameter” theory which is widely used to predict aggregate morphology, and retrace the historical development of wormlike micelles (WLMs), and the unique characteristics that WLMs possess, as well as generic models used to describe them. Finally, we state the motivation and the organization of this monograph.

Yujun Feng, Zonglin Chu, Cécile A. Dreiss

Chapter 2. Thermo-responsive Wormlike Micelles

Abstract

This chapter summarizes findings on the simplest trigger applied to wormlike micellar: temperature. Thermo-thinning systems are not discussed since a viscosity decrease with temperature is a rather general characteristic of most systems. Instead, the unique thermo-viscosifying behaviour displayed by some WLMs and the possibility of imparting a pseudo “sol/gel” transition in specific systems are extensively addressed. These two types of systems show a transition from either a low-viscosity fluid or a viscoelastic solution to a gel-like state by tuning the temperature. The thermo-thickening behaviour and the underlying mechanisms of various types of thermo-thickening wormlike micellar systems (non-ionic, cationic, anionic, and zwitterionic) are discussed in terms of molecular structure–property relationships.

Yujun Feng, Zonglin Chu, Cécile A. Dreiss

Chapter 3. Light-responsive Wormlike Micelles

Abstract

UV/Vis light as a trigger displays a set of advantages over other types of stimuli in terms of its “clean” character, low cost, and precise spatial localization, and for these reasons it has been widely exploited in the development of smart materials. Light-responsive wormlike micelles take advantage of light-induced cis–trans isomerization or dimerization of light-sensitive surfactants or additives containing a suitable chromophore. These changes alter the packing of surfactant molecules in the aggregates and drive micellar transitions between wormlike micelles and other structures, thus tuning the viscoelasticity. This chapter summarizes two types of strategies in manipulating light-sensitive wormlike micelles—either to incorporate light-sensitive additives into classical existing wormlike micellar solutions or to directly introduce light-sensitive functional moieties on the surfactant molecules. In both cases, the worms self-assemble or disassemble upon alternate UV/Vis light irradiation.

Yujun Feng, Zonglin Chu, Cécile A. Dreiss

Chapter 4. pH-Responsive Wormlike Micelles

Abstract

pH has been known for a long time and frequently used as a facile, inexpensive trigger to control molecular assemblies and thereby the bulk properties of the corresponding solutions. pH-responsive WLMs have been developed not only based on commercially available surfactants in the presence of hydrotropes, but also through the design of surfactant mixture composition and surfactant architecture. This chapter introduces pH-responsive wormlike micellar systems fabricated through the introduction of hydrotropes to conventional surfactant-based wormlike micellar systems, in appropriate mixtures of surfactants, or by modifying the surfactant molecular architecture with pH-sensitive functional groups, either the hydrophilic head or the hydrophobic tail. It is worth pointing out that a disadvantage of this trigger is that the cyclic addition of acid and base may deteriorate the repeated use of the wormlike micellar systems.

Yujun Feng, Zonglin Chu, Cécile A. Dreiss

Chapter 5. CO2-Responsive Wormlike Micelles

Abstract

Despite its extensive use, pH as a trigger has several drawbacks including the need of stoichiometric quantities of acid and base, the accumulation of by-products, and costly disposal. In this context, the weak acid gas, CO₂, represents an interesting alternative because it is inexpensive, relatively benign, and can be easily removed, thus is free of contamination. In addition, CO₂ can be completely removed by streaming an inert gas into the solution and/or mild heating, which allows the CO₂-reactive functional groups to resort to their initial forms. Presented in this chapter are four classes of CO₂-responsive wormlike micellar systems, three of which are based on amines, either located on the hydrotrope molecules or on the skeleton of long-chain surfactants. Carboxylate-based anionic wormlike micelles are also sensitive to CO₂, but the pre-formed wormlike micelles are ruptured by the presence of CO₂ and thus the macroscopic viscosity drops. The “CO₂/air” switchable system based on a C22-tailed tertiary amine is particularly attractive for practical applications because it provides a cost-effective, environment-friendly, and low-energy way to regulate the viscoelasticity in aqueous media simply by bubbling CO₂ or air at ambient temperature, without the need of heat or the use of an inert gas such as N₂ or Ar.

Yujun Feng, Zonglin Chu, Cécile A. Dreiss

Chapter 6. Other Types of Smart Wormlike Micelles

Abstract

In comparison with the widely reported triggers described in previous chapters—namely temperature, pH, and light—this chapter discusses triggers which have been far less documented: redox potential and hydrocarbons and their use to control the assembly and properties of wormlike micelles. In addition, recent reports of multiple stimuli-responsive wormlike micelles are also described, as well as smart reverse wormlike micelles, to complete this collection of “unconventional” smart wormlike micelles.

Yujun Feng, Zonglin Chu, Cécile A. Dreiss

Chapter 7. Applications of Smart Wormlike Micelles

Abstract

The end purpose of formulating smart wormlike micelles is undoubtedly to use them for practical applications. Their micellar structure and reversibly switchable viscoelastic properties offer opportunities for uses where controllable encapsulation and thickening are needed. A series of potential applications are described in this chapter, including biomedicine, cleaning, as electrorheological and photo-rheological fluids, for templating, and drag reduction, amongst others. However, the only current success stories of SWLMs commercial applications come from oil well stimulation processes, including as clean fracturing fluids and for self-diverting acidizing, which are discussed at length in this chapter.

Yujun Feng, Zonglin Chu, Cécile A. Dreiss

Titel: Smart Wormlike Micelles
verfasst von: Yujun Feng
Zonglin Chu
Cécile A. Dreiss
Copyright-Jahr: 2015
Verlag: Springer Berlin Heidelberg
Electronic ISBN: 978-3-662-45950-8
Print ISBN: 978-3-662-45949-2
DOI: https://doi.org/10.1007/978-3-662-45950-8

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