| Thermophoretic motion of water nanodroplets confined inside carbon nanotubes HA Zambrano, JH Walther, P Koumoutsakos, IF Sbalzarini Nano letters 9 (1), 66-71, 2009 | 156 | 2009 |
| Early regimes of water capillary flow in slit silica nanochannels E Oyarzua, JH Walther, A Mejía, HA Zambrano Physical Chemistry Chemical Physics 17 (22), 14731-14739, 2015 | 79 | 2015 |
| Thermally driven molecular linear motors: a molecular dynamics study HA Zambrano, JH Walther, RL Jaffe The Journal of chemical physics 131 (24), 2009 | 63 | 2009 |
| Carbon Nanotubes as Thermally-Induced Water Pumps E Oyarzua, J Walther, C Megaridis, P Koumoutsakos, HA Zambrano ACS Nano, 2017 | 60 | 2017 |
| Slip divergence of water flow in graphene nanochannels: The role of chirality E Wagemann, E Oyarzua, JH Walther, HA Zambrano Physical Chemistry Chemical Physics, 2017 | 60 | 2017 |
| Molecular dynamics simulations of water on a hydrophilic silica surface at high air pressures HA Zambrano, JH Walther, RL Jaffe Journal of Molecular Liquids 198, 107-113, 2014 | 57 | 2014 |
| Electrokinetic Transport of Monovalent and Divalent Cations in Silica Nanochannels S Prakash, HA Zambrano, K Rangharajan, E Rosenthal-Kim, N Vasquez, ... Microfluidics and Nanofluidics 20 (8), 1-12, 2016 | 34 | 2016 |
| Electrokinetic transport in silica nanochannels with asymmetric surface charge S Prakash, HA Zambrano, M Fuest, C Boone, E Rosenthal-Kim, ... Microfluidics and Nanofluidics, 1-10, 2015 | 28 | 2015 |
| Water thermophoresis in Carbon Nanotubes: the interplay between thermophoretic and friction forces E Oyarzua, JH Walther, HA Zambrano Physical Chemistry Chemical Physics, 2018 | 25 | 2018 |
| Effect of an external electric field on capillary filling of water in hydrophilic silica nanochannels NK Karna, AR Crisson, E Wagemann, JH Walther, HA Zambrano Physical Chemistry Chemical Physics 20 (27), 18262-18270, 2018 | 22 | 2018 |
| Effect of the meniscus contact angle during early regimes of spontaneous imbibition in nanochannels NK Karna, EE Oyarzua, JH Walther, HA Zambrano Physcal Chemistry Chemical Physcis, 2016 | 16 | 2016 |
| Electrokinetic transport in a water–chloride nanofilm in contact with a silica surface with discontinuous charged patches HA Zambrano, M Pinti, AT Conlisk, S Prakash Microfluidics and nanofluidics 13, 735-747, 2012 | 16 | 2012 |
| Water Flow in Silica Nanopores Coated by Carbon Nanotubes from a Wetting Translucency Perspective E Wagemann, J Walther, E Cruz-Chú, H Zambrano Journal of Physical Chemistry C, 2019 | 13 | 2019 |
| Wall embedded electrodes to modify electroosmotic flow in silica nanoslits HA Zambrano, N Vásquez, E Wagemann Physical Chemistry Chemical Physics 18 (2), 1202-1211, 2016 | 12 | 2016 |
| Effect of charge inversion on nanoconfined flow of multivalent ionic solutions A Rojano, A Córdoba, J Walther, HA Zambrano Physical Chemistry Chemical Physics 1 (1), 10.1039/D1CP02102H, 2022 | 7 | 2022 |
| Water flow enhancement in amorphous silica nanochannels coated with monolayer graphene E Wagemann, D Becerra, JH Walther, HA Zambrano MRS Communications 10 (3), 428-433, 2020 | 6 | 2020 |
| Water Flow in Graphene Nanochannels driven by Imposed Thermal Gradients: The Role of Flexural Phonons E Oyarzua, JH Walther, HA Zambrano Physical Chemistry Chemical Physics 1 (10.1039/D2CP04093J), 1-10, 2023 | 4 | 2023 |
| Water flow in a polymeric nanoslit channel with graphene and hexagonal boron nitride wall coatings: An atomistic study D Becerra, A Córdoba, JH Walther, HA Zambrano Physics of Fluids 35 (10), 2023 | 3 | 2023 |
| The effect of air solubility on the Kapitza resistance of the copper-water interface W Situ, HA Zambrano, JH Walther Journal of Molecular Liquids 366, 120049, 2022 | 2 | 2022 |
| Controlling the electroosmotic transport in nanochannels: effect of divalent counter-ions H Zambrano, T Conlisk 51st AIAA Aerospace Sciences Meeting including the New Horizons Forum and …, 2013 | 2 | 2013 |
Jens Honore WaltherDTU Denmark在 dtu.dk 的电子邮件经过验证
