Plasmonic Metal Nanostructures

This book focuses on plasmonic nanostructures and their applications, for instance, in catalyis, sensing, spectroscopy, thin-film analysis and optoelectronics.

Autorentext

Caixia Kan is the professor at College of Science at Nanjing University of Aeronautics and Astronautics in Nanjing, China. She graduated with PhD degree in 2004 from Institute of Solid-State Physics, Chinese Academy of Sciences. In the duration of PhD study, she worked in Max-Planck-Institute of Microstructure Physics on the cooperation of TEM research. Professor Kan was awarded as an excellent teacher and young academic leader in the Qinglan Project of Jiangsu Province in 2008 and 2014, respectively. In 2020, she won the sixth Young Optical Science and Technology Award of Jiangsu Optical Society. Professor Kan has published more than 150 papers about plasmonic metal nanostructure, semiconductor micro/nano structure and optoelectronic devices.

Klappentext

Firsthand insights on a unique class of optoelectronic materials, covering technologies and applications in catalysis, sensing, and spectroscopy Plasmonic Metal Nanostructures provides broad coverage of the field of plasmonic technologies, from fundamentals to real-world applications such as highly sensitive spectroscopy and surface analysis techniques, summarizing the recent progress in plasmonics and their applications, with a focus on comprehensive and authoritative discussions of fabrication and characterization of the materials and their technological uses. The text also addresses current trends and advances in materials for plasmonics, such as nanostructures with novel shapes, composite nanostructures, and thin films. Starting with an overview of optical properties in materials from macro- to micro- and nanoscale, the text then moves on to discuss the fundamentals and dielectric modifications and advanced characterization methods of plasmonic nanostructures. Next, the latest development of metal nanostructures, such as core-shell and porous nanorods, nanowires for conductive films, new star-like nanoplates, different open nanostructures, and metal-semiconductor composite nanostructures, are explained in detail. The final portion of the text discusses applications of plasmonics for semiconductor optoelectronic devices, catalysis, sensing, SERS (surface-enhanced Raman Spectroscopy), and energy. Written by a highly qualified academic, Plasmonic Metal Nanostructures covers sample topics such as:

• Drude model for free electron gas, dielectric function of the free electron gas, surface plasmon polaritons, plasmon at metal-vacuum interface, and surface plasmon effects
• Drude-Lorentz model of metal nanoparticles, dielectric properties of complex nanostructures, optical property analysis of isolated nanoparticles, and numerical simulation of optical properties
• One-dimensional Au nanostructures, core-shell nanostructures, alloy Au/Ag nanorods, porous nanorods, and yolk-shell nanostructures

• FCC nanoplates, Au nanoplates with novel and well-defined shapes, metal decorated semiconductors, and optical properties of Au NBP-embedded nanostructures Providing complete coverage of plasmonic nanostructures and their applications in catalysis, sensing, spectroscopy, thin-film, analysis, optoelectronics, and a variety of other fields. The book about Plasmonic Metal Nanostructures is an essential resource for materials scientists, physics researchers and photochemists, along with catalytic, biomedical, and physical chemists.

  Inhalt
  PART I INTRODUCTION OF PLASMONICS

  1 INTRODUCTION FOR THIS BOOK
  1.1 Human beings never stop exploring light
  1.2 Charming metal color
  1.3 Natural development of plasmonics
  1.4 About this book

  PART II FUNDAMENTAL AND LATEST DEVELOPMENT IN THE PLASMONICS

  2 THEORETICAL BACKGROUNDS OF PLASMONICS
  2.1 Introduction
  2.2 Drude model for free electron gas
  2.3 Dielectric function of the free electron gas
  2.4 Surface plasmon polaritons
  2.5 Plasmon at metal-vacuum interface
  2.6 Excitation and detection of SPP
  2.7 Surface plasmon effects
  2.8 Summary of this chapter

  3 FUNDAMENTAL AND DIELECTRONIC MODIFICATION OF PLASMONIC NANOSTRUCTURES
  3.1 Introduction
  3.2 Drude-Lorentz model of metal nanoparticles
  3.3 Dielectric properties of complex nanostructures
  3.4 Optical property analysis of isolated nanoparticles
  3.5 Numerical simulation of optical properties
  3.6 Coupling nanostructure assembly with high sensitivity
  3.7 Conclusion

  4 ADVANCED CHARACTERIZATIONS FOR PLASMONIC NANOSTRUCTURES
  4.1 Introduction
  4.2 Optical property characterization technology
  4.3 Electron microscopy
  4.4 Conclusion

  PART III PRECISE PREPARATION OF PLASMONIC NANOSTRUCTURES

  5 CORE-SHELL AND POROUS NANORODS WITH HOT SPOTS
  5.1 Introduction
  5.2 One-dimensional Au nanostructures
  5.3 Core-shell nanostructures
  5.4 Alloy Au/Ag nanorods
  5.5 Porous nanorods
  5.6 Yolk-shell nanostructures
  5.7 Concluding remarks

  6 NANOWIRES FOR CONDUCTIVE FILMS AND ELECTROMAGNETIC SHIELDING
  6.1 Introduction
  6.2 One-dimensional metal nanowires
  6.3 Conductive films
  6.4 Conclusion

  7 NORMAL AND NOVEL NANOPLATES FOR UNDERSTANDING GROWTH MECHANISM
  7.1 Introduction
  7.2 General considerations for fcc nanoplates
  7.3 Au nanoplates with novel and well-defined shapes
  7.4 Summary of this chapter

  8 HOLLOW AND OPEN NANOSTRUCTURES WITH ENHANCED ACTIVITY
  8.1 Introduction
  8.2 Hollow nanostructures
  8.3 Open nanostructures
  8.4 Optical property of Au NBP-embedded nanostructures
  8.5 Conclusion and outlook

  9 METAL-SEMICONDUCTOR COMPOSITE NANOSTRUCTURES
  9.1 Introduction
  9.2 Metal decorated semiconductor
  9.3 Core-shell structure and properties modulation
  9.4 Conclusion

  PART IV APPLICATION EXPLORATION OF PLASMONIC NANOSTRUCTURES

  10 HOT ELECTRON EFFECT ON OPTOELECTRONIC DEVICE
  10.1 Introduction
  10.2 Light-emitting device and modulation
  10.3 Hot-electron photodetection
  10.4 Conclusion

  11 APPLICATIONS IN CATALYSIS AND ENERGY
  11.1 Introduction
  11.2 Electrocatalysis
  11.3 Photocatalysis
  11.4 Solar vapor generation
  11.5 Conclusions and outlook

  12 APPLICATIONS IN SERS AND SENSOR
  12.1 Introduction
  12.2 Typical SERS substrates
  12.3 SERS for detection and sensor
  12.4 Conclusion and outlook