Differences

This shows you the differences between two versions of the page.

Link to this comparison view

literature:per_category [2009/08/14 15:58]
jonas
literature:per_category [2011/10/29 19:08] (current)
Line 5: Line 5:
  
 ++++ theory | ++++ theory |
 +^ ^
 +|**J Wang, M, Wang, and ZX Li**(2008):|
 +|[[literature:wang_08|Lattice Evolution Solution for the Nonlinear
 +                Poisson-Boltzmann Equation in Confined Domains]]|
 ^ ^ ^ ^
 |**Jonas Latt, Bastien Chopard, Orestis Malaspinas, Michel Deville, and Andreas Michler**(2008):| |**Jonas Latt, Bastien Chopard, Orestis Malaspinas, Michel Deville, and Andreas Michler**(2008):|
 |[[literature:latt_08|Straight velocity boundaries in the lattice Boltzmann method]]| |[[literature:latt_08|Straight velocity boundaries in the lattice Boltzmann method]]|
 ^ ^ ^ ^
-|**J Wang, M Wang, and ZX Li**(2006):|+|**Zhaoli Guo and Chuguang Zheng**(2008):| 
 +|[[literature:guo_08|Analysis of lattice Boltzmann equation for microscale gas 
 +                flows: Relaxation times, boundary conditions and the 
 +                Knudsen layer]]| 
 +^ ^ 
 +|**M.M. Dupin, I. Halliday, C.M. Care, and L.L. Munna**(2008):| 
 +|[[literature:dupin_08|Lattice Boltzmann modelling of blood cell dynamics]]| 
 +^ ^ 
 +|**J Wang, M, Wang, and ZX Li**(2007):| 
 +|[[literature:wang_07|A Lattice Boltzmann Algorithm for Fluid-Solid Conjugate 
 +                Heat Transfer.]]| 
 +^ ^ 
 +|**J Wang, M, Wang, and ZX Li**(2006):|
 |[[literature:wang_06|Lattice Poisson-Boltzmann Simulations of Electro-osmotic |[[literature:wang_06|Lattice Poisson-Boltzmann Simulations of Electro-osmotic
                 Flows in Microchannels]]|                 Flows in Microchannels]]|
Line 58: Line 74:
 ^ ^ ^ ^
 |**Chenghai Sun**(2000):| |**Chenghai Sun**(2000):|
-|[[literature:sun_00|Simulations of Compressible Flows with Strong Shocks by an Adaptive Lattice Boltzmann Model]]|+|[[literature:sun_00|Simulations of Compressible Flows with Strong Shocks by an 
 +                Adaptive Lattice Boltzmann Model]]|
 ^ ^ ^ ^
 |**Christopher M. Teixeira**(1998):| |**Christopher M. Teixeira**(1998):|
Line 104: Line 121:
  
 ++++ application | ++++ application |
 +^ ^
 +|**M Wang and QJ Kang**(2009):|
 +|[[literature:wang_09c|Electrokinetic transport in microchannels with random
 +                roughness]]|
 +^ ^
 +|**M Wang and N Pan**(2009):|
 +|[[literature:wang_09|Elastic property of multiphase composites with random
 +                microstructures.]]|
 +^ ^
 +|**M Wang, QJ Kang, and N Pan**(2009):|
 +|[[literature:wang_09b|Thermal conductivity enhancement of carbon fiber composites]]|
 +^ ^
 +|**M Wang and N Pan**(2008):|
 +|[[literature:wang_08c|Predictions of Effective Properties of Complex Multiphase
 +                Materials]]|
 +^ ^
 +|**M Wang and N Pan**(2008):|
 +|[[literature:wang_08b|Modeling and prediction of the effective thermal
 +                conductivity of random open-cell porous foams]]|
 +^ ^
 +|**F Meng, M Wang, and ZX Li**(2008):|
 +|[[literature:meng_08|Lattice Boltzmann Simulations of Conjugate Heat Transfer
 +                in High-Frequency Oscillating Flows]]|
 +^ ^
 +|**M Wang, F Meng, and N Pan**(2007):|
 +|[[literature:wang_07i|Transport properties of functionally graded materials]]|
 +^ ^
 +|**M Wang and N Pan**(2007):|
 +|[[literature:wang_07h|Numerical analyses of effective dielectric constant of
 +                multiphase micro porous media]]|
 +^ ^
 +|**M Wang, J He, J Yu, and N Pan**(2007):|
 +|[[literature:wang_07g|Lattice Boltzmann modeling of the effective thermal
 +                conductivity for fibrous materials]]|
 +^ ^
 +|**M Wang, N Pan, J Wang, and S Chen**(2007):|
 +|[[literature:wang_07f|Mesoscopic simulations of phase distribution effects on the
 +                effective thermal conductivity of microgranular porous media]]|
 +^ ^
 +|**M Wang, J Wang, N Pan, S Chen, and J He**(2007):|
 +|[[literature:wang_07e|Three dimensional effect on the effective thermal
 +                conductivity of porous media]]|
 +^ ^
 +|**M Wang, J Wang, N Pan, and S Chen**(2007):|
 +|[[literature:wang_07d|Mesoscopic Predictions of the Effective Thermal Conductivity
 +                of Microscale Random Porous Media]]|
 +^ ^
 +|**M Wang and S Chen**(2007):|
 +|[[literature:wang_07c|Electroosmosis in homogeneously charged micro- and nanoscale
 +                random porous media]]|
 +^ ^
 +|**M Wang, JK Wang, and S Chen**(2007):|
 +|[[literature:wang_07b|Roughness and Cavitations effects on Electro-osmotic Flows
 +                in Rough Microchannels using the Lattice
 +                Poisson-Boltzmann Methods]]|
 +^ ^
 +|**M Wang, JK Wang, S Chen, and N Pan**(2006):|
 +|[[literature:wang_06b|Electrokinetic Pumping Effects of Charged Porous Media in
 +                Microchannels using the Lattice Poisson-Boltzmann Method]]|
 ^ ^ ^ ^
 |**Sebastian Geller, Manfred Krafczyk, Jonas Tolke, Stefan Turek, and Jaroslav Hron**(2006):| |**Sebastian Geller, Manfred Krafczyk, Jonas Tolke, Stefan Turek, and Jaroslav Hron**(2006):|
 |[[literature:geller_06|Benchmark computations based on lattice-Boltzmann, finite element and finite volume methods for laminar flows]]| |[[literature:geller_06|Benchmark computations based on lattice-Boltzmann, finite element and finite volume methods for laminar flows]]|
 +^ ^
 +|**J Wang, M Wang, and ZX Li**(2005):|
 +|[[literature:wang_05|Lattice Boltzmann simulations of mixing enhancement by the
 +                electro-osmotic flow in microchannels]]|
 ++++ ++++
  
Line 117: Line 197:
 |[[literature:zhao_93|Chaotic and resonant streamlines in the ABC flow]]| |[[literature:zhao_93|Chaotic and resonant streamlines in the ABC flow]]|
 ++++ ++++
 +
  
 ==== Sub-categories ==== ==== Sub-categories ====
Line 122: Line 203:
  
 ++++ model, analysis, review | ++++ model, analysis, review |
 +^ ^
 +|**J Wang, M, Wang, and ZX Li**(2007):|
 +|[[literature:wang_07|A Lattice Boltzmann Algorithm for Fluid-Solid Conjugate
 +                Heat Transfer.]]|
 +^ ^
 +|**J Wang, M, Wang, and ZX Li**(2006):|
 +|[[literature:wang_06|Lattice Poisson-Boltzmann Simulations of Electro-osmotic
 +                Flows in Microchannels]]|
 ^ ^ ^ ^
 |**Xiaowen Shan, Xue-Feng Yuan, and Hudong Chen**(2006):| |**Xiaowen Shan, Xue-Feng Yuan, and Hudong Chen**(2006):|
Line 173: Line 262:
  
 ++++ thermal, turbulence, complex | ++++ thermal, turbulence, complex |
 +^ ^
 +|**M.M. Dupin, I. Halliday, C.M. Care, and L.L. Munna**(2008):|
 +|[[literature:dupin_08|Lattice Boltzmann modelling of blood cell dynamics]]|
 +^ ^
 +|**M Wang and S Chen**(2007):|
 +|[[literature:wang_07c|Electroosmosis in homogeneously charged micro- and nanoscale
 +                random porous media]]|
 +^ ^
 +|**M Wang, JK Wang, and S Chen**(2007):|
 +|[[literature:wang_07b|Roughness and Cavitations effects on Electro-osmotic Flows
 +                in Rough Microchannels using the Lattice
 +                Poisson-Boltzmann Methods]]|
 +^ ^
 +|**M Wang, JK Wang, S Chen, and N Pan**(2006):|
 +|[[literature:wang_06b|Electrokinetic Pumping Effects of Charged Porous Media in
 +                Microchannels using the Lattice Poisson-Boltzmann Method]]|
 ^ ^ ^ ^
 |**Zhaoli Guo, Baochang Shi, and Chuguang Zheng**(2002):| |**Zhaoli Guo, Baochang Shi, and Chuguang Zheng**(2002):|
Line 185: Line 290:
  
 ++++ high_knudsen, compressible | ++++ high_knudsen, compressible |
 +^ ^
 +|**Zhaoli Guo and Chuguang Zheng**(2008):|
 +|[[literature:guo_08|Analysis of lattice Boltzmann equation for microscale gas
 +                flows: Relaxation times, boundary conditions and the
 +                Knudsen layer]]|
 ^ ^ ^ ^
 |**Chenghai Sun**(2000):| |**Chenghai Sun**(2000):|
-|[[literature:sun_00|Simulations of Compressible Flows with Strong Shocks by an Adaptive Lattice Boltzmann Model]]|+|[[literature:sun_00|Simulations of Compressible Flows with Strong Shocks by an 
 +                Adaptive Lattice Boltzmann Model]]|
 ^ ^ ^ ^
 |**Y. H. Qian and S. A. Orszag**(1993):| |**Y. H. Qian and S. A. Orszag**(1993):|
 
literature/per_category.txt · Last modified: 2011/10/29 19:08 (external edit)
 
RSS - 2011 © FlowKit.com
Except where otherwise noted, text, pictures and animations on this site are licensed under a Creative Commons Attribution-Share Alike 3.0 License.