Modelling of Cylindrical Nanostructures: A New Method for High-Resolution Coverage Spectroscopy

Theory and Modelling of Cylindrical Nanostructures presents a new method for the evaluation of the coverage distribution of randomly deposited nanoparticles, such as single-walled carbon nanotubes and Ag nanowires over the substrate (oxides, SiO2, Si3N4, glass etc), through height measurements performed by scanning probe microscopy techniques, like Atomic Force Microscopy (AFM). The deposition of nanoparticles and how they aggregate in multiple layers over the substrate is one of the most important aspects of solution processed materials determining devices performances. The coverage spectroscopy method presented in the book is strongly application oriented and has several implementations supporting advanced surface analysis through many scanning probe microscopy techniques. This book will therefore be of great value to both materials scientists and physicists who conduct research in this area. Demonstrates how to measure quantitatively the composition of coverage of nanoparticles, exploiting the distribution of the nanoparticles into several aggregatesExplains the method for evaluation of the coverage distribution of a substrate by randomly deposited nanoparticles utilizing experimental data provided by scanning probe microscopy techniquesExplains how the methods outlined can be used for a range of spectroscopy applications INDICE: Chapter I - The coverage theory and the Delta model approximation 1. The physical model 2. Simulations 3. The coverage error theory 4. Experimental verification - Part I 5. A model for multiple CNT intersections 6. Generalized coverage theory 7. Experimental verification - Part II 8. Matlab© scripts 9. AFM Measured CNT height density database Chapter II - Statistical diameter modelling and height density functions 1. The general equation of the height density 2. Deterministic diameter 3. Uniform diameter density 4. Rayleigh diameter density 5. Gaussian-Harmonic (GH) diameter density 6. Measured diameter density 7. Summary of height statistics 8. Gaussian convolution with height densities 9. Comparison among statistical models Chapter III - The generalized coverage theory and experimental verification 1. Redefining the coverage physical model 2. Coverage solution: DESIGN? mode 3. Coverage solution: MEASURE mode 4. CNTs with random direction 5. Experimental verifications Chapter IV - The Gaussian-Harmonic model of the substrate height density 1. A new model for the substrate height 2. The Gaussian-Harmonic height density 3. MMSE fitting 4. Application to randomized height densities 5. Measurements of Silver nanowires Conclusions

• ISBN: 978-0-323-52731-6
• Editorial: William Andrew
• Encuadernacion: Rústica
• Páginas: 416
• Fecha Publicación: 01/05/2017
• Nº Volúmenes: 1
• Idioma: Inglés