Carbon Nanotubes And Nanosensors Vibration Buckling And Ballistic Impact Isaac Elishakoff by Isaac Elishakoff, Demetris Pentaras, Kevin Dujat, Claudia Versaci, Giuseppe Muscolino, Joel Storch, Simon Bucas, Noel Challamel, Toshiaki Natsuki, Yingyan Zhang, Chien Ming Wang, Guillaume Ghyselinck(auth.) 9781118562000, 9781848213456, 1118562003, 184821345X instant download after payment.

The main properties that make carbon nanotubes (CNTs) a promising technology for many future applications are: extremely high strength, low mass density, linear elastic behavior, almost perfect geometrical structure, and nanometer scale structure. Also, CNTs can conduct electricity better than copper and transmit heat better than diamonds. Therefore, they are bound to find a wide, and possibly revolutionary use in all fields of engineering.
The interest in CNTs and their potential use in a wide range of commercial applications; such as nanoelectronics, quantum wire interconnects, field emission devices, composites, chemical sensors, biosensors, detectors, etc.; have rapidly increased in the last two decades. However, the performance of any CNT-based nanostructure is dependent on the mechanical properties of constituent CNTs. Therefore, it is crucial to know the mechanical behavior of individual CNTs such as their vibration frequencies, buckling loads, and deformations under different loadings.
This title is dedicated to the vibration, buckling and impact behavior of CNTs, along with theory for carbon nanosensors, like the Bubnov-Galerkin and the Petrov-Galerkin methods, the Bresse-Timoshenko and the Donnell shell theory.Content:
Chapter 1 Introduction (pages 1–12):
Chapter 2 Fundamental Natural Frequencies of Double?Walled Carbon Nanotubes (pages 13–45):
Chapter 3 Free Vibrations of the Triple?Walled Carbon Nanotubes (pages 47–63):
Chapter 4 Exact Solution for Natural Frequencies of Clamped?Clamped Double?Walled Carbon Nanotubes (pages 65–83):
Chapter 5 Natural Frequencies of Carbon Nanotubes Based on a Consistent Version of Bresse–Timoshenko Theory (pages 85–96):
Chapter 6 Natural Frequencies of Double?Walled Carbon Nanotubes Based on Donnell Shell Theory (pages 97–107):
Chapter 7 Buckling of a Double?Walled Carbon Nanotube (pages 109–137):
Chapter 8 Ballistic Impact on a Single?Walled Carbon Nanotube (pages 139–147):
Chapter 9 Clamped?Free Double?Walled Carbon Nanotube?Based Mass Sensor (pages 149–201):
Chapter 10 Some Fundamental Aspects of Non?local Beam Mechanics for Nanostructures Applications (pages 203–268):
Chapter 11 Surface Effects on the Natural Frequencies of Double?Walled Carbon Nanotubes (pages 269–289):
Chapter 12 Summary and Directions for Future Research (pages 291–295):