Mass Transfer Modeling in Microchannel

  1. S. Mondal, S. De, “Pressure Driven transport of neutral macro-solute in microchannel with porous wall at High Surface Potential”, International Journal of Heat and Mass Transfer, 104 (2017) 574-583.
  2. M. Mondal, R. P. Mishra and S. De, “Combined electroosmotic and pressure driven flow in a microchannel at high zeta potential and overlapping electrical double layer”, International Journal of Thermal Sciences, 86 (2014) 48-59.
  3. S. Mondal and S. De, “Mass Transfer of a neutral solute in Porous Microchannel under Streaming Potential”, Electrophoresis, 35 (2014) 681-690.
  4. S. Mondal and S. De, “Effects of non-Newtonian power law rheology on mass transport of a neutral solute for electro-osmotic flow in a porous microtube”, Biomicrofluidics, 7 (2013) 044113.
  5. S. Mondal and S. De, “Mass transport in a porous microchannel for non-Newtonian fluid with electrokinetic effects”, Electrophoresis, 34 (5) 668-673, 2013.
  6. S. Mondal, Chhaya, S. De, “Identification of fouling mechanism during ultrafiltration of stevia extract”, Food and Bioprocess Technology, 6, (2013) 931-940.
  7. N. Vennela, S. Mondal, S. Bhattacharjee and S. De, “Sherwood number in flow through parallel porous plates (microchannel) due to pressure and electroosmotic flow” AIChE Journal, 58 (6) (2012) 1693-1703.
  8. N. Vennela, S. Bhattacharjee and S. De, “Sherwood number in porous microtube due to combined pressure and electroosmotically driven flow”, Chemical Engineering Science, 66 (2011) 6515-6524.
  9. H. Sharma, N. Vasu and S. De, “Mass transfer during catalytic reaction in electroosmotically driven flow in a channel microreactor”, Heat and Mass Transfer, 47 (5) (2011) 541-550.
  10. N. Vasu and S. De, “Electroviscous effects in purely pressure driven flow and stationary plane analysis in electroosmotic flow of power-law fluids in a slit microchannel”, International Journal of Engineering Science, 48 (2010) 1641-1658.
  11. N. Vasu and S. De, “Electroosmotic flow of power-law fluids at high zeta potentials”, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 368 (2010) 44-52.