Surfactant Formulation Engineering using HLD and NAC
- 1st Edition - April 28, 2025
- Latest edition
- Editors: Edgar Acosta, Jeffrey Harwell, David A. Sabatini
- Language: English
Surfactants are molecules that contain groups that are water-loving (hydrophilic) and oil-loving (lipophilic). The central question in formulations is often which of the two… Read more
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Description
Description
Surfactants are molecules that contain groups that are water-loving (hydrophilic) and oil-loving (lipophilic). The central question in formulations is often which of the two portions dominate the behavior of the surfactant. For many years that question was answered in terms of the surfactant structure only. However, the modern view is that the hydrophilic-lipophilic nature of the surfactant is the result of surfactant structure and formulation conditions (nature of the oil, temperature, aqueous phase composition) as captured by a semi-empirical equation called the hydrophilic-lipophilic difference (HLD). The HLD is a dimensionless number that indicate the approach to the point where the surfactant inverts its solubility from being water-soluble (negative HLD) to oil-soluble (positive HLD). The HLD alone is a good indicator of how the formulation could behave but it does not produce any formulation property that can be used to predict product performance. The net-average curvature (NAC) are a set of equations that take the value of HLD to predict the properties of the formulation, such as oil (and/or water) solubilization capacity, interfacial tension, phase diagrams, contact angle and others.
Surfactant Formulation Engineering using HLD and NAC will not only introduce the reader to HLD-NAC but also to the practical use of these concepts in numerous applications ranging from application in the petroleum industry, to environmental remediation, to food, cosmetic and pharmaceutical applications, and even nanotechnology. The last part of the book will look at the molecular origins of the empirical terms in HLD via the Integrated Free Energy Model (IFEM).
Surfactant Formulation Engineering using HLD and NAC will not only introduce the reader to HLD-NAC but also to the practical use of these concepts in numerous applications ranging from application in the petroleum industry, to environmental remediation, to food, cosmetic and pharmaceutical applications, and even nanotechnology. The last part of the book will look at the molecular origins of the empirical terms in HLD via the Integrated Free Energy Model (IFEM).
Key features
Key features
- Concentrates on the HLD and NAC, providing industrially-relevant examples
- Provides the only single depository for HLD parameters
- Balances theory and application, with insights from both academic and industrial authors
- Includes examples relevant to a wide range of fields, with practical guides on how to go from the formulation objective(s) to an actual formulation design
Readership
Readership
Professionals in chemical, oil chemical, pharmaceutical, food formulation and other industries working with surfactant formulation and applicationsHLD-NAC short courses given to and by industrial groups
Table of contents
Table of contents
1. Surfactant hydrophilicity-lipophilicity and its assessment
2. Effect of lipophilic and hydrophilic additives on the hydrophilic-lipophilic difference (HLD)
3. Design Aspects and Practices of Surfactant Formulations Used in Chemical EOR and Surfactant-Enhanced Aquifer Remediation
4. HLD-guided surfactant design for enhanced oil recovery applications
5. Detergency System Design: From Hydrophile-Lipophile Balance (HLB) to Hydrophilic-Lipophilic Deviation (HLD)
6. HLD-guided design of vegetable oil extraction technology
7. Formulation of microemulsion-based biofuels via the HLD framework
8. Catastrophic Inversion of Epoxy Emulsions
9. Using HLD as a Framework for Solutions Without your Parameters
10. High-throughput HLD-guided formulation design for latex and agrochemical formulations
11. High Throughput HLD Surfactant Characterization and Formulation
12. Net-Average Curvature (NAC) fundamentals and applications
13. A Formulator’s Guide to HLD-NAC
14. Basic HLD and NAC Applied to Household Cleaner Formulation – Advantages and Limitations
15. Engineering cold water detergents with the HLD-NAC
16. Engineering separation processes with the HLD-NAC
17. Engineering nanoscale materials with the HLD-NAC
18. Microemulsion Flash Calculations using an HLD-NAC Based Equation of State
19. Molecular thermodynamic basis: the Integrated Free Energy Model (IFEM)
2. Effect of lipophilic and hydrophilic additives on the hydrophilic-lipophilic difference (HLD)
3. Design Aspects and Practices of Surfactant Formulations Used in Chemical EOR and Surfactant-Enhanced Aquifer Remediation
4. HLD-guided surfactant design for enhanced oil recovery applications
5. Detergency System Design: From Hydrophile-Lipophile Balance (HLB) to Hydrophilic-Lipophilic Deviation (HLD)
6. HLD-guided design of vegetable oil extraction technology
7. Formulation of microemulsion-based biofuels via the HLD framework
8. Catastrophic Inversion of Epoxy Emulsions
9. Using HLD as a Framework for Solutions Without your Parameters
10. High-throughput HLD-guided formulation design for latex and agrochemical formulations
11. High Throughput HLD Surfactant Characterization and Formulation
12. Net-Average Curvature (NAC) fundamentals and applications
13. A Formulator’s Guide to HLD-NAC
14. Basic HLD and NAC Applied to Household Cleaner Formulation – Advantages and Limitations
15. Engineering cold water detergents with the HLD-NAC
16. Engineering separation processes with the HLD-NAC
17. Engineering nanoscale materials with the HLD-NAC
18. Microemulsion Flash Calculations using an HLD-NAC Based Equation of State
19. Molecular thermodynamic basis: the Integrated Free Energy Model (IFEM)
Product details
Product details
- Edition: 1
- Latest edition
- Published: May 21, 2025
- Language: English
About the editors
About the editors
EA
Edgar Acosta
Edgar Acosta is a Professor in the Department of Chemical Engineering and Applied Chemistry at the University of Toronto. He received his BSc in Chemical Engineering from the Universidad del Zulia (Venezuela) in 1996, and his MSc and PhD in Chemical Engineering from the University of Oklahoma, Norman, Oklahoma, in 2000 and 2004, respectively. He has published 90 research articles in the area of colloids, complex fluids, and formulation engineering.
Affiliations and expertise
Professor, Department of Chemical Engineering and Applied Chemistry, University of Toronto, Toronto, ON, CanadaJH
Jeffrey Harwell
Jeffrey Harwell works at the University of Oklahoma in OK, USA.
Affiliations and expertise
University of Oklahoma, OK, USADS
David A. Sabatini
David A Sabatini works at University of Oklahoma in USA
Affiliations and expertise
University of Oklahoma, USAView book on ScienceDirect
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