Self Propelled Particles

Selfpropelled particles-This chapter introduces the concept of selfpropulsion and its significance in active matter, setting the stage for the exploration of microswimmers

Tsallis entropy-An overview of Tsallis entropy and its relevance to the statistical mechanics of active systems, providing insights into the behavior of selfpropelled particles

Active fluid-Delve into the dynamics of active fluids, exploring how individual particles interact with the medium and influence macroscopic properties

Dirk Helbing-Learn about Dirk Helbing’s contributions to the theory of collective behavior and the modeling of selfpropelled particle systems

Percolation threshold-Understand the concept of percolation threshold and its impact on the collective behavior of selfpropelled particles in disordered systems

Collective motion-Explore the phenomena of collective motion in systems of selfpropelled particles and its connection to statistical physics

Vicsek model-An introduction to the Vicsek model, a fundamental model in the study of collective motion, providing a framework for understanding flocking behavior

Nanomotor-Discover the role of nanomotors in the movement of selfpropelled particles and their applications in various fields, from medicine to robotics

Swarm behaviour-Study the principles of swarm behavior, examining how simple individual rules lead to complex, collective patterns in large systems of microswimmers

Microswimmer-Gain an indepth understanding of the mechanisms and physics behind microswimmers, and how they can be utilized in research and technology

Clustering of selfpropelled particles-Investigate how selfpropelled particles tend to cluster under certain conditions, exploring the factors influencing this behavior

Symmetry breaking of escaping ants-This chapter examines the phenomenon of symmetry breaking in collective systems, with a focus on ants escaping from a confined space

Stringnet liquid-Learn about stringnet liquids and their connection to the behavior of selfpropelled particles in complex, highly correlated systems

Random sequential adsorption-Understand the process of random sequential adsorption, a model for the placement of particles on a surface and its relevance to selfpropelled particles

Sriram Ramaswamy-A tribute to Sriram Ramaswamy’s pioneering work on the dynamics of active matter, with a focus on his contributions to understanding collective behavior

Active matter-This chapter explores the broader field of active matter, examining its properties, behavior, and applications in both theoretical and practical contexts

Landau–Zener formula-Learn about the Landau–Zener formula and its applications to the study of quantum transitions in systems of selfpropelled particles

Scissors Modes-Discover the concept of scissors modes and their implications for understanding the collective dynamics of selfpropelled particles

Micromotor-Investigate the technology and physics behind micromotors, focusing on their potential uses in medicine, environmental monitoring, and more

Maya Paczuski-This chapter highlights the work of Maya Paczuski, examining her contributions to the study of complex systems and active matter

Sharon Glotzer-Learn about Sharon Glotzer’s research on selfassembly and active matter, particularly in relation to the design of new materials and devices