Self Propulsion: Mechanisms and Dynamics of Microbial Motion

Chapters Brief Overview:

1: Selfpropulsion: An introduction to the concept of selfpropelled particles and their relevance in technology and nature.

2: Hydrophobe: Investigates the properties of hydrophobic materials, critical for microswimmer functionality.

3: Active matter: Delve into the principles of active matter, shedding light on its importance in microscale systems.

4: Ultrahydrophobicity: Focuses on ultrahydrophobic materials that push the boundaries of microswimmer design.

5: Nanofluid: Examines how nanofluids contribute to selfpropulsion by providing optimal environments for movement.

6: Micromotor: Discusses micromotor development and their realworld applications in fields like medicine and environmental monitoring.

7: Marangoni effect: Explores the Marangoni effect, an essential physical principle in the propulsion of particles.

8: Leidenfrost effect: Delves into the Leidenfrost effect and its application in creating selfpropelled systems.

9: Diffusiophoresis and diffusioosmosis: Investigates the movement of particles driven by concentration gradients.

10: Microswimmer: An indepth look at the role of microswimmers in a variety of cuttingedge technologies.

11: Nanomotor: Explores the miniaturization of motors and how they revolutionize the field of nanorobotics.

12: Wetting: Focuses on the physics of wetting phenomena and its importance in microswimmer propulsion.

13: Nanorobotics: A detailed exploration of how microswimmers integrate with the emerging field of nanorobotics.

14: Clustering of selfpropelled particles: Explores the behavior of selfpropelled particles when they cluster and move as a unit.

15: Liquid marbles: Discusses liquid marbles and their fascinating role in selfpropulsion at the microscale.

16: Coffee ring effect: A thorough examination of the coffee ring effect and its implications for microswimmer systems.

17: Edward Bormashenko: Highlights the contributions of Edward Bormashenko to the field of microswimmers and selfpropulsion.

18: Selfpropelled particles: Reviews the characteristics and functionality of selfpropelled particles in modern science.

19: Surface tension biomimetics: Investigates how surface tension biomimetics are used to design efficient microswimmers.

20: Droplet cluster: Discusses the formation of droplet clusters and their potential applications in selfpropulsion.

21: Collective motion: Explores the concept of collective motion in selfpropelled particles, essential for understanding largescale systems.

This book not only serves as a critical resource for those in academia and industry but also provides an indepth understanding of microswimmer technology’s potential. Whether you’re a student seeking to broaden your knowledge or a professional looking to innovate in the realm of nanotechnology, "Self Propulsion" provides the foundational principles, realworld applications, and emerging technologies needed to understand this fascinating field.