Surface Plasmon: Understanding the Principles and Applications of Nanoscale Light Driven Motion

Chapters Brief Overview:

1: Surface plasmon: An introduction to surface plasmon phenomena and its significance in modern research.

2: Plasmonic solar cell: The integration of plasmonics with solar cells to enhance energy absorption.

3: Nanoruler: How plasmonic properties enable precise nanometrology for advanced fabrication.

4: Extraordinary optical transmission: Explores how surface plasmon resonance drives unique optical transmission effects.

5: Plasmonic metamaterial: A detailed analysis of metamaterials designed to manipulate electromagnetic waves at the nanoscale.

6: Plasmonic nanoparticles: Focuses on nanoparticles that harness plasmonic effects for applications in sensing and imaging.

7: Plasmonics: A comprehensive examination of the field of plasmonics and its technological innovations.

8: Plasmonic nanolithography: The use of plasmonic effects in nanolithography for creating smaller and more efficient devices.

9: Plasmonic lens: The role of plasmonic lenses in overcoming the diffraction limit in optics.

10: Ravindra Kumar Sinha (physicist): A tribute to Ravindra Kumar Sinha and his contributions to plasmonics research.

11: Localized surface plasmon: A deep dive into the phenomena of localized plasmon resonances in metallic nanoparticles.

12: Spaser: Explains the concept of the spaser, a light source driven by plasmonic effects, and its applications.

13: Metamaterial absorber: An exploration of metamaterial absorbers for energy harvesting and electromagnetic shielding.

14: Surface plasmon resonance: Describes the principle of surface plasmon resonance and its applications in biosensing.

15: Spoof surface plasmon: Discusses spoof surface plasmon for manipulating electromagnetic waves in unconventional materials.

16: Graphene plasmonics: Investigates how graphene’s unique properties lead to new plasmonic applications.

17: Nanophotonics: An overview of the interaction of light with nanoscale materials and its implications for future technology.

18: Plasmon: A further exploration of the fundamental aspects of plasmon behavior in different materials.

19: Surface plasmon polariton: Describes the surface plasmon polariton, a hybrid of light and electron waves, in detail.

20: Surface plasmon resonance microscopy: Focuses on how surface plasmon resonance enhances microscopy for biological studies.

21: Nanolaser: Concludes with a detailed study of nanolasers powered by plasmonic effects and their impact on photonics.

By exploring each chapter, readers gain a deep understanding of the role surface plasmons play in current and future technological innovations, particularly in the realm of nanoscale devices and energy systems. This book serves as a key resource for anyone passionate about plasmonics and its potential in shaping nextgeneration technologies. Whether you are a professional, student, or hobbyist, this book will deepen your knowledge of the topic and open new possibilities for your work or studies.