| 511 - 512 |
Fundamentals of electrophoresis 2006
Gas B |
| 513 - 518 |
Oscillating electrolytes
Hruska V, Jaros M, Gas B |
| 519 - 525 |
A new type of migrating zone boundary in electrophoresis: 2. Transient sample zone shapes
Gebauer P, Mala Z, Bocek P |
| 526 - 533 |
Electrophoresis of soft particles: Analytic approximations
Ohshima H |
| 534 - 541 |
The unified equation for the evaluation of first order reactions in dynamic electrophoresis
Trapp O |
| 542 - 552 |
Capillary electrophoresis for thermodynamic and kinetic studies of peptidyl-proline isomerization by the theoretical plate height model
Newman CID, McGuffin VL |
| 553 - 562 |
Calibration of migration times of variable salinity samples with internal standards in capillary electrophoresis
Riaz A, Chung DS |
| 563 - 571 |
Loading capacity of carrier ampholytes based buffers in capillary electrophoresis
Busnel JM, Descroix S, Godfrin D, Hennion MC, Peltre G |
| 572 - 583 |
Origin of peak asymmetry and isotherm nonlinearity in micellar electrokinetic chromatography: Variation of peak shape with buffer concentration
Williamson Y, Davis JM |
| 584 - 610 |
Surface treatment and characterization: Perspectives to electrophoresis and lab-on-chips
Pallandre A, de Lambert B, Attia R, Jonas AM, Viovy JL |
| 611 - 619 |
Electroosmotic flow in a rectangular channel with variable wall zeta-potential: Comparison of numerical simulation with asymptotic theory
Datta S, Ghosal S, Patankar NA |
| 620 - 627 |
A method for simultaneously determining the zeta potentials of the channel surface and the tracer particles using microparticle image velocimetry technique
Yan DG, Yang C, Nguyen NT, Huang XY |
| 628 - 639 |
Assessment of Joule heating and its effects on electroosmotic flow and electrophoretic transport of solutes in microfluidic channels
Tang GY, Yan DG, Yang C, Gong HQ, Chai JC, Lam YC |
| 640 - 649 |
Estimation of Joule heating effect on temperature and pressure distribution in electrokinetic-driven microchannel flows
Chein RY, Yang YC, Lin YS |
| 650 - 660 |
Nonstationary electroosmotic flow in open cylindrical capillaries
Mishchuk NA, Gonzalez-Caballero F |
| 661 - 671 |
Nonstationary electroosmotic flow in closed cylindrical capillaries
Mishchuk NA, Gonzalez-Caballero F |
| 672 - 676 |
Variation of zeta-potential with temperature in fused-silica capillaries used for capillary electrophoresis
Evenhuis CJ, Guijt RM, Macka M, Marriott PJ, Haddad PR |
| 677 - 685 |
The promise of nanotechnology for separation devices - from a top-down approach to nature-inspired separation devices
Eiijkel JCT, van den Berg A |
| 686 - 693 |
Effective Debye length in closed nanoscopic systems: A competition between two length scales
Tessier F, Slater GW |
| 694 - 702 |
Continuous separation of microparticies by size with direct current-dielectrophoresis
Kang KH, Kang YJ, Xuan XC, Li DQ |
| 703 - 715 |
Influence of particle-particle interactions and particles rotational motion in traveling wave dielectrophoresis
Aubry N, Singh P |
| 716 - 725 |
Theoretical and nomenclatural considerations of capillary electrochromatography with monolithic stationary phases
Vegavri A, Guttman A |
