Transport properties of long straight nano-channels in electrolyte solutions: A systematic approach

Advances in Colloid and Interface Science

Volumn 168, Issue 1-2, 2011, Pages 278-291

  Yaroshchuk, Andriy E ^a  

^a UNIVERSITAT POLITÈCNICA DE CATALUNYA   (Spain)

Author keywords

Capillary electrophoresis; Electro viscosity; Electroosmosis; Ion; Nano channel; Salt diffusion permeability; Salt reflection coefficient; Separation

Indexed keywords

ANALYTES; ANALYTICAL EXPRESSIONS; APPROXIMATE SOLUTION; DEBYE SCREENING LENGTH; DIFFUSION PERMEABILITY; DISTRIBUTION COEFFICIENT; DOUBLE ELECTRIC LAYER; ELECTRIC DOUBLE LAYER; ELECTRO-VISCOSITY; ELECTROKINETIC; ELECTROLYTE SOLUTIONS; ELECTROSTATIC ADSORPTION; ELECTROSTATIC POTENTIALS; FUNCTIONALS; GENERIC EXPRESSION; LOCAL THERMODYNAMIC EQUILIBRIUM; NANO CHANNELS; POISSON-BOLTZMANN APPROACH; POISSON-BOLTZMANN EQUATIONS; QUASI-EQUILIBRIUM; RIGOROUS SOLUTION; SALT DIFFUSION; SALT DIFFUSION PERMEABILITY;

ADSORPTION; BOLTZMANN EQUATION; CAPILLARY ELECTROPHORESIS; ELECTROLYTES; ELECTROPHORETIC MOBILITY; ELECTROSTATICS; ENERGY CONVERSION; IONS; POISSON EQUATION; REFLECTION; VISCOSITY;

OSMOSIS;

EID: 80053561904     PISSN: 00018686     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.cis.2011.03.009     Document Type: Article

References (61)

1. H. Chang, and L.Y. Yeo Electrokinetically-driven microfluidics and nanofluidics 2010 Cambridge University Press
2. X. Xuan Ion separation in nanofluidics Electrophoresis 29 18 2008 3737 3743
3. X. Xuan, and D. Li Solute separation in nanofluidic channels: pressure-driven or electric field-driven? Electrophoresis 28 4 2007 627 634 (Pubitemid 46394790)
4. S. Pennathur, and J.G. Santiago Electrokinetic transport in nanochannels. 1 Theory Anal Chem 77 21 2005 6772 6781
5. S.K. Griffiths, and R.H. Nilson Optimization of charged species separation by autogenous electric field-flow fractionation in nano-scale channels Electrophoresis 31 5 2010 832 842
6. Y.C. Wang, A.L. Stevens, and J.Y. Han Million-fold pre-concentration of proteins and peptides by nanofluidic filter Anal Chem 77 14 2005 4293 4299 (Pubitemid 41542245)
7. P. Kim, S.J. Kim, J. Han, and K.Y. Suh Stabilization of ion concentration polarization using a heterogeneous nanoporous junction Nano Lett 10 1 2010 16 23
8. S.J. Kim, L.D. Li, and J. Han Amplified electrokinetic response by concentration polarization near nanofluidic channel Langmuir 25 13 2009 7759 7765
9. S.J. Kim, Y. Wang, J.H. Lee, H. Jang, and J. Han Concentration polarization and nonlinear electrokinetic flow near a nanofluidic channel Phys Rev Lett 99 4 2007 044501
10. Y. Wang, K. Pant, Z.J. Chen, W. Diffey, P. Ashley, and S. Sundaram Numerical analysis of nanofluidic sample pre-concentration in hydrodynamic flow M. Laudon, B. Romanowicz, NSTI nanotech 2008, vol 3, technical proceedings - microsystems, photonics, sensors, fluidics, modeling, and simulation 2008 CRC Press-Taylor & Francis Group 442 445
11. H. Daiguji, Y. Oka, and K. Shirono Nanofluidic diode and bipolar transistor Nano Lett 5 11 2005 2274 2280 (Pubitemid 41698952)
12. H. Daiguji, P.D. Yang, and A. Majumdar Ion transport in nanofluidic channels Nano Lett 4 1 2004 137 142 (Pubitemid 38167879)
13. H. Daiguji Ion transport in nanofluidic channels Chem Soc Rev 39 3 2010 901 911
14. I. Vlassiouk, and Z.S. Siwy Nanofluidic diode Nano Lett 7 3 2007 552 556 (Pubitemid 46516025)
15. I. Vlassiouk, T.R. Kozel, and Z.S. Siwy Biosensing with nanofluidic diodes J Am Chem Soc 131 23 2009 8211 8220
16. E.B. Kalman, I. Vlassiouk, and Z.S. Siwy Nanofluidic bipolar transistors Adv Mater 20 2 2008 293-+
17. Z.S. Siwy, and S. Howorka Engineered voltage-responsive nanopores Chem Soc Rev 39 3 2010 1115 1132
18. S. Bhattacharyya, Z. Zheng, and A.T. Conlisk Electro-osmotic flow in two-dimensional charged micro- and nanochannels J Fluid Mech 540 2005 247 267 (Pubitemid 41478937)
19. M.M. Gregersen, M.B. Andersen, G. Soni, C. Meinhart, and H. Bruus Numerical analysis of finite Debye-length effects in induced-charge electro-osmosis Phys Rev E 79 6 2009 066316
20. S. Bhattacharyya, and A.K. Nayak Combined effect of surface roughness and heterogeneity of wall potential on electroosmosis in microfluidic/nanofuidic channels J Fluids Eng Trans ASME 132 4 2010 041103
21. J.C. Ramirez, and A.T. Conlisk Formation of vortices near abrupt nano-channel height changes in electro-osmotic flow of aqueous solutions Biomed Microdevices 8 4 2006 325 330 (Pubitemid 44697348)
22. L. Chen, and A.T. Conlisk Electroosmotic flow and particle transport in micro/nano nozzles and diffusers Biomed Microdevices 10 2 2008 289 298
23. L. Chen, and A.T. Conlisk Effect of nonuniform surface potential on electroosmotic flow at large applied electric field strength Biomed Microdevices 11 1 2009 251 258
24. W. Zhang, and D. Li Simulation of low speed 3D nanochannel flow Microfluid Nanofluid 3 4 2007 417 425 (Pubitemid 47023673)
25. T. Postler, Z. Slouka, M. Svoboda, M. Pribyl, and D. Snita Parametrical studies of electroosmotic transport characteristics in submicrometer channels J Colloid Interface Sci 320 1 2008 321 332
26. H.S. White, and A. Bund Ion current rectification at nanopores in glass membranes Langmuir 24 5 2008 2212 2218 (Pubitemid 351500985)
27. J. Hrdlicka, P. Cervenka, M. Pribyl, and D. Snita Mathematical modeling of AC electroosmosis in microfluidic and nanofluidic chips using equilibrium and non-equilibrium approaches J Appl Electrochem 40 5 2010 967 980
28. G. Hu Solute transport in nanochannels with roughness-like structures Proc. ASME Micro/Nanoscale Heat and Mass Transfer International Conference Amer Soc Mechanical Engineers 1 2010 95 101
29. Y.S. Choi, and S.J. Kim Electrokinetic flow-induced currents in silica nanofluidic channels J Colloid Interface Sci 333 2 2009 672 678
30. Y. Wang, K. Pant, Z. Chen, G. Wang, W.F. Diffey, and P. Ashley Numerical analysis of electrokinetic transport in micro-nanofluidic interconnect preconcentrator in hydrodynamic flow Microfluid Nanofluid 7 5 2009 683 696
31. Q.S. Pu, J.S. Yun, H. Temkin, and S.R. Liu Ion-enrichment and ion-depletion effect of nanochannel structures Nano Lett 4 6 2004 1099 1103 (Pubitemid 38859989)
32. S.J. Kim, and J. Han Nonlinear electrokinetic flow: theory, experiment, and potential applications Iutam Symposium Advances Micro Nanofluidics 15 2009 3 17
33. A. Mani, T.A. Zangle, and J.G. Santiago On the propagation of concentration polarization from microchannel-nanochannel interfaces Part I: analytical model and characteristic analysis Langmuir 25 6 2009 3898 3908
34. J. Taylor, and C.L. Ren Application of continuum mechanics to fluid flow in nanochannels Microfluid Nanofluid 1 4 2005 356 363 (Pubitemid 41489730)
35. J. Taylor, and C.L. Ren Evaluation of continuum mechanics for electroosmotic flow in nanosize structures ICMM 2005: 3rd International Conference on Microchannels and Minichannels, Pt B Amer Soc Mechanical Engineers 2005 627 633 (Pubitemid 41610419)
36. C.L. Ren, and D.Q. Li Improved understanding of the effect of electrical double layer on pressure-driven flow in microchannels Anal Chim Acta 531 1 2005 15 23 (Pubitemid 40255169)
37. A.T. Conlisk, J. McFerran, Z. Zheng, and D. Hansford Mass transfer and flow in electrically charged micro- and nanochannels Anal Chem 74 9 2002 2139 2150 (Pubitemid 34465414)
38. Z. Zheng, D.J. Hansford, and A.T. Conlisk Effect of multivalent ions on electroosmotic flow in micro- and nanochannels Electrophoresis 24 17 2003 3006 3017 (Pubitemid 38094246)
39. F. Baldessari Electrokinetics in nanochannels - Part I. electric double layer overlap and channel-to-well equilibrium J Colloid Interface Sci 325 2 2008 526 538
40. F. Baldessari, and J.G. Santiago Electrokinetics in nanochannels. Part I. electric double layer overlap and channel-to-well equilibrium (vol 325, pg 526, 2008) J Colloid Interface Sci 331 2 2009 549-549
41. Z. Yuan, A.L. Garcia, G.P. Lopez, and D.N. Petsev Electrokinetic transport and separations in fluidic nanochannels Electrophoresis 28 4 2007 595 610 (Pubitemid 46394788)
42. D.N. Petsev Theory of transport in nanofluidic channels with moderately thin electrical double layers: effect of the wall potential modulation on solutions of symmetric and asymmetric electrolytes J Chem Phys 123 24 2005 244907
43. D.N. Petsev, and G.P. Lopez Electrostatic potential and electroosmotic flow in a cylindrical capillary filled with symmetric electrolyte: analytic solutions in thin double layer approximation J Colloid Interface Sci 294 2 2006 492 498 (Pubitemid 41679343)
44. V.N. Shilov Equations for the non-reversible hydrodynamics of the boundary layer in an electrolyte solution Colloid Surf a Physicochem Eng Asp 142 2-3 1998 375 379 (Pubitemid 28529160)
45. A.E. Yaroshchuk Osmosis and reverse-osmosis in fine-porous charged diaphragms and membranes Adv Colloid Interface Sci 60 1-2 1995 1 93
46. J.W. Lorimer Phenomenological coefficients and frames of reference for transport processes in liquids and membranes.3. Theory of convective contributions to isothermal and non-isothermal transport in ionic membranes J Membr Sci 14 3 1983 275 302 (Pubitemid 13590995)
47. D. Burgreen, and F.R. Nakache Electrokinetic flow in ultrafine capillary slits J Phys Chem 68 5 1964 1084
48. S. Pennathur, and J.G. Santiago Electrokinetic transport in nanochannels. 1. Theory (vol 77, pg 6772, 2005) Anal Chem 78 3 2006 972-972
49. S.K. Griffiths, and R.H. Nilson Charged species transport, separation, and dispersion in nanoscale channels: Autogenous electric field-flow fractionation Anal Chem 78 23 2006 8134 8141 (Pubitemid 44871782)
50. A.E. Yaroshchuk Negative rejection of ions in pressure-driven membrane processes Adv Colloid Interface Sci 139 1-2 2008 150 173
51. A. Yaroshchuk, O. Zhukova, M. Ulbricht, and V. Ribitsch Electrochemical and other transport properties of nanoporous track-etched membranes studied by the current switch-off technique Langmuir 21 15 2005 6872 6882 (Pubitemid 41084477)
52. S.A. Miller, K.C. Kelly, and A.T. Timperman Ionic current rectification at a nanofluidic/microfluidic interface with an asymmetric microfluidic system Lab Chip 8 10 2008 1729 1732
53. P.W. Bohn Nanoscale control and manipulation of molecular transport in chemical analysis Annu Rev Anal Chem 2 2009 279 296
54. R. Dhopeshwarkar, R.M. Crooks, D. Hlushkou, and U. Tallarek Transient effects on microchannel electrokinetic filtering with an ion-permselective membrane Anal Chem 80 4 2008 1039 1048 (Pubitemid 351272336)
55. D.G. Strickland, M.E. Suss, T.A. Zangle, and J.G. Santiago Evidence shows concentration polarization and its propagation can be key factors determining electroosmotic pump performance Sens Actuator B Chem 143 2 2010 795 798
56. S. Pennathur, and J.G. Santiago Electrokinetic transport in nanochannels. 2. Experiments Anal Chem 77 21 2005 6782 6789 (Pubitemid 41547271)
57. S.S. Dukhin Nonequilibrium electric surface phenomena Adv Colloid Interface Sci 44 1993 1 134
58. S.S. Dukhin, and B.V. Derjaguin Electrokinetic phenomena E. Matijevic, Surface and colloid science 1974
59. S. Qian, B. Das, and X. Luo Diffusioosmotic flows in slit nanochannels J Colloid Interface Sci 315 2 2007 721 730 (Pubitemid 47445529)
60. F.A. Morrison, and J.F. Osterle Electrokinetic energy conversion in ultrafine capillaries J Chem Phys 43 6 1965 2111
61. I.H. Huisman, P. Pradanos, J.I. Calvo, and A. Hernandez Electroviscous effects, streaming potential, and zeta potential in polycarbonate track-etched membranes J Membr Sci 178 1-2 2000 79 92 (Pubitemid 30645765)