Non-Newtonian Microfluidics
Microfluidics has seen a remarkable growth over recent decades, with its extensive applications in engineering, medicine, biology, chemistry, etc. Many of these real applications of microfluidics involve the handling of complex fluids, such as whole blood, protein solutions, and polymeric solutions,...
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Mei, Lanju edt Non-Newtonian Microfluidics Basel MDPI - Multidisciplinary Digital Publishing Institute 2022 1 electronic resource (252 p.) text txt rdacontent computer c rdamedia online resource cr rdacarrier Microfluidics has seen a remarkable growth over recent decades, with its extensive applications in engineering, medicine, biology, chemistry, etc. Many of these real applications of microfluidics involve the handling of complex fluids, such as whole blood, protein solutions, and polymeric solutions, which exhibit non-Newtonian characteristics—specifically viscoelasticity. The elasticity of the non-Newtonian fluids induces intriguing phenomena, such as elastic instability and turbulence, even at extremely low Reynolds numbers. This is the consequence of the nonlinear nature of the rheological constitutive equations. The nonlinear characteristic of non-Newtonian fluids can dramatically change the flow dynamics, and is useful to enhance mixing at the microscale. Electrokinetics in the context of non-Newtonian fluids are also of significant importance, with their potential applications in micromixing enhancement and bio-particles manipulation and separation. In this Special Issue, we welcomed research papers, and review articles related to the applications, fundamentals, design, and the underlying mechanisms of non-Newtonian microfluidics, including discussions, analytical papers, and numerical and/or experimental analyses. English Technology: general issues bicssc History of engineering & technology bicssc microfluidics Janus droplet OpenFOAM volume of fluid method adaptive dynamic mesh refinement shear-thinning fluid electroosmosis elastic instability non-Newtonian fluid Oldroyd-B model electroosmotic flow micromixing performance heterogeneous surface potential wall obstacle power-law fluid bvp4c RK4 technique brownian motion porous rotating disk maxwell nanofluid thermally radiative fluid von karman transformation hybrid nanofluid entropy generation induced magnetic field convective boundary conditions thermal radiations stretching disk viscoelastic material group similarity analysis thermal relaxation time parametric investigation variable magnetic field error analysis viscoelastic fluid microfluid direction-dependent viscous dissipation chemical reaction finite element procedure hybrid nanoparticles heat and mass transfer rates joule heating tri-hybrid nanoparticles Soret and Dufour effect boundary layer analysis finite element scheme heat generation constructive and destructive chemical reaction particle separation viscoelastic flow inertial focusing spiral channel transient two-layer flow power-law nanofluid heat transfer Laplace transform nanoparticle volume fraction effective thermal conductivity fractal scaling Monte Carlo porous media power-law model bioheat equation human body droplet deformation viscoelasticity wettable surface dielectric field droplet migration wettability gradient 3-0365-4642-1 3-0365-4641-3 Qian, Shizhi edt Mei, Lanju oth Qian, Shizhi oth |
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English |
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Qian, Shizhi Mei, Lanju Qian, Shizhi |
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Qian, Shizhi Mei, Lanju Qian, Shizhi |
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Non-Newtonian Microfluidics |
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Non-Newtonian Microfluidics |
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Non-Newtonian Microfluidics |
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Non-Newtonian Microfluidics |
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Non-Newtonian Microfluidics |
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Non-Newtonian Microfluidics |
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Non-Newtonian Microfluidics |
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non-newtonian microfluidics |
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MDPI - Multidisciplinary Digital Publishing Institute |
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2022 |
physical |
1 electronic resource (252 p.) |
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3-0365-4642-1 3-0365-4641-3 |
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Not Illustrated |
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AT meilanju nonnewtonianmicrofluidics AT qianshizhi nonnewtonianmicrofluidics |
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(CKB)5600000000483087 (oapen)https://directory.doabooks.org/handle/20.500.12854/91223 (EXLCZ)995600000000483087 |
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Non-Newtonian Microfluidics |
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