Frontier in Nanoscale Flows Fractional Calculus and Analytical Methods |
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Editor:
| Lewis, Roland He, Ji-Huan Liu, Hong-yan |
ISBN: | 978-1-78441-330-9 |
Publication Date: | Jul 2014 |
Publisher: | Emerald Publishing Limited
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Book Format: | Ebook |
List Price: | USD $199.00 |
Book Description:
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co-rotating vortices, compressible flow, particle strength exchange, Variational iteration method, Variational iteration method, air permeability, fractal medium, fractional heat conduction, fractional Navier-Stokes equations, Variational iteration method, Fluid in charged jet, Thermal and hydrodynamic performance, Convection-diffusion equation, Gray-encoded evolution algorithm, Parameter optimization, Precision, Twin-jet flow, Taylor-series expansion moment method, isopotential...
More Descriptionco-rotating vortices, compressible flow, particle strength exchange, Variational iteration method, Variational iteration method, air permeability, fractal medium, fractional heat conduction, fractional Navier-Stokes equations, Variational iteration method, Fluid in charged jet, Thermal and hydrodynamic performance, Convection-diffusion equation, Gray-encoded evolution algorithm, Parameter optimization, Precision, Twin-jet flow, Taylor-series expansion moment method, isopotential electrodes, Aligned fibers, ANSYS, nanoporous fiber, Homotopy perturbation method, Heat equation, Unknown source term, Nano-channel, Rarefied gas flow, Velocity slip, Approximate solution, Lie symmetry method, MHD Falkner-Skan flow, Padé technique, Empirical Mode Decomposition, Hilbert spectrum, Hilbert-Huang Transform, Multi-scale, Streamflow, particle thermal properties, suspension plasma spray, Numerical simulation, Fixed point iteration, Homogenization theory, Tensile property, Titanium matrix composite, convective term, fractional derivative, moving interface, fractional derivative, convection-diffusion problems, Molecular dynamics, Electrospinning, Finite element, Analytical solution, laminar flow, Differential Evolution, accuracy, Electrospinning, nanoparticle, Inverse problem, He's polynomials, Vortex method, Numerical simulation