Dissipative particle dynamics (DPD): Fundamentals and Applications in Colloid and Interface Science is one of the most efficient mesoscale simulation methodologies for studying soft matter systems. Applied to nanostructured materials of supramolecular architecture, DPD bridges the gap between the microscopic atomistic and macroscopic continuum length and time scales.?The book comprehensively presents the fundamentals of DPD?theoretical formulations and computational strategies and provides a practical guidance for applications of DPD models to various colloidal and interfacial phenomena involving phase separations, self-assembly and transport in complex fluids, polymeric, surfactant, nanoparticle, and biological systems. In addition, the book contains instructive advice on efficient implementation of the DPD models in open-source computational packages. Since introduction of the principles of DPD methodology thirty years ago, multiple efforts have been performed to improve the computational basis of DPD and to devise advanced versions and modifications of the original DPD framework. The progress in parametrization techniques that can reproduce engineering properties of experimental systems attracted a lot of interest from the industrial community longing to use DPD models to characterize, help design and optimize the practical products. While there are numerous research papers, there is no book dedicated to the dissipative particle dynamics that provides a critical review of various DPD formulations, serves as a comprehensive reference source of multifaceted interdisciplinary applications, and provides a practical guidance for efficient computational implementation.
- Comprehensive discussion on the foundations and latest advances in the DPD methodology, showcasing multiple interdisciplinary applications with appropriate examples, whilst providing a practical guidance to the choice and computational implementation of DPD models
- Balanced synergistic presentation of the theoretical foundations, modern computational methodologies, and practical applications of dissipative particle dynamics suitable for interdisciplinary readership, including academics, industrial researchers, and students
- Critical analysis of various DPD formulations with pragmatic recommendations how to choose, parameterize, and implement DPD models for computational simulations of specific systems
- Demonstration of the multidisciplinary nature of DPD models on diverse practically relevant examples in materials, chemical, and biological science, and engineering