ADVANCED COMPUTATIONAL TECHNIQUES IN NANOSCIENCE -- ADVANCED COMPUTATIONAL TECHNIQUES IN NANOSCIENCE -- Contents -- About the Editors -- Preface -- Introduction -- Properties of Carbon Nanotubes -- 1.1. Structures of a Crystal Lattice of Diamond and Graphite -- 1.2. Graphene -- 1.3. Carbon Nanotubes -- 1.4. Fullerenes -- 1.5. Classification of Nanotubes -- 1.6. Chirality -- 1.7. Diameter, Chirality Angle and the Mass of Single-walled Nanotube -- Micro and Nanoscale Systems -- 2.1. Introduction -- Capillary Effects -- Specific Electrical Resistance of Carbon Nanotubes ( ) -- -- Emission Properties of Carbon Nanotubes -- 2.2. Electro-kinetic Processes in Micro and Nanoscale Systems -- 2.3. Continuum Hypothesis -- 2.4. The Molecular Dynamics Method -- 2.5. Van der Waals Equation. Corresponding States Law -- Rheological Properties and Structure of the Liquid in Nanotubes -- 3.1. Slippage of the Fluid Particles Near the Wall -- 3.2. The Density of the Liquid Layer Near a Wall of Carbon Nanotube -- 3.3. The Effective Viscosity of the Liquid in a Nanotube -- 3.4. The Release of Energy due to the Collapse of the Nanotube -- Fluid Flow in Nanotubes -- 4.1. Introduction -- 4.2. Modeling in Nanohydromecanics -- The Results of the Calculations -- The Flow of Fluid with an Empty Interlayer -- Nanohydromechanics -- 5.1. Nanophenomenon in Oil Production -- 5.2. Petroleum Composition -- 5.3. Nanobubbles of Gas, Oil in the Pore Channels and Water -- 5.4. Properties of Aluminum -- 5.5. The Use of Aluminum Powder in Oil Production -- References -- Index.