Self Propelled Particles

“Self Propelled Particles” offers an indepth exploration of the groundbreaking concept of biohybrid microswimmers, which has increasingly become essential for understanding the dynamics of selfpropulsion in biological systems and nanotechnology. By delving into topics such as active matter, collective motion, and swarm behavior, this book equips readers with the knowledge and tools to navigate one of the most exciting frontiers in modern science and technology

Selfpropelled particles-A comprehensive introduction to the concept of selfpropelled particles, laying the foundation for understanding the behavior of biohybrids in diverse environments

Sriram Ramaswamy-Exploration of Sriram Ramaswamy's contributions to the field of active matter, offering insights into collective dynamics and the physics behind the motion of selfpropelled particles

Dirk Helbing-A focus on Dirk Helbing's research into the statistical mechanics of collective motion, providing a deeper understanding of the collective behavior of autonomous entities

Micromotor-A chapter dedicated to the design and applications of micromotors, showing their relevance in the development of autonomous systems for various technological advancements

Collective motion-Delving into how individual agents, such as selfpropelled particles, interact to form largescale coordinated behaviors in complex systems

Active fluid-This chapter examines the concept of active fluids, which are key to understanding how selfpropelled particles behave in dynamic environments

Microswimmer-A detailed discussion on microswimmers and their applications in biotechnology, nanomedicine, and environmental monitoring, highlighting their potential in practical applications

Maya Paczuski-An analysis of Maya Paczuski's work on the mathematical modeling of collective behaviors and phase transitions in selforganizing systems

Percolation threshold-Examining the percolation threshold, a key concept in the study of critical phenomena and phase transitions in systems of selfpropelled particles

Active matter-A further exploration of active matter, focusing on how its properties can be applied to the development of novel materials and technologies

Swarm behaviour-An investigation into swarm behavior in the context of biohybrid microswimmers, highlighting the relevance of natural systems to artificial systems

Tsallis entropy-A discussion of Tsallis entropy, which offers a unique perspective on the statistical mechanics of nonequilibrium systems

Clustering of selfpropelled particles-An exploration of the factors that lead to the clustering of selfpropelled particles and their implications for the study of complex systems

Symmetry breaking of escaping ants-Understanding how symmetry breaking occurs in systems of selfpropelled agents, using ants as a model for escape dynamics

Stringnet liquid-An examination of the theoretical model of stringnet liquids, which has significant implications for quantum physics and the behavior of selforganizing systems

Nanomotor-A discussion on nanomotors and their applications in medicine and technology, showing their importance in the field of nanotechnology

Scissors Modes-A deep dive into scissors modes and their relevance to understanding the collective motion of particles in active systems

Sharon Glotzer-A focus on Sharon Glotzer’s research, which has contributed to our understanding of selfassembly processes and their applications in nanotechnology

Random sequential adsorption-This chapter explores random sequential adsorption processes, offering insights into the behavior of selfpropelled particles in nonequilibrium conditions

Landau–Zener formula-A look at the LandauZener formula and its significance in the study of nonadiabatic transitions in active matter systems