| On the electric field enhancement and performance of SPR gas sensor based on graphene for visible and near infrared PK Maharana, R Jha, P Padhy Sensors and Actuators B: Chemical 207, 117-122, 2015 | 134 | 2015 |
| On the field enhancement and performance of an ultra-stable SPR biosensor based on graphene PK Maharana, P Padhy, R Jha IEEE Photonics Technology Letters 25 (22), 2156-2159, 2013 | 97 | 2013 |
| Near-field optical trapping in a non-conservative force field MA Zaman, P Padhy, L Hesselink Scientific reports 9 (1), 649, 2019 | 44 | 2019 |
| Solenoidal optical forces from a plasmonic Archimedean spiral MA Zaman, P Padhy, L Hesselink Physical Review A 100 (1), 013857, 2019 | 25 | 2019 |
| Adjoint method for estimating Jiles-Atherton hysteresis model parameters MA Zaman, PC Hansen, LT Neustock, P Padhy, L Hesselink Journal of Applied Physics 120 (9), 2016 | 25 | 2016 |
| Dielectrophoresis-assisted plasmonic trapping of dielectric nanoparticles MA Zaman, P Padhy, PC Hansen, L Hesselink Physical Review A 95 (2), 023840, 2017 | 24 | 2017 |
| Metal wire waveguide based all plasmonic refractive index sensor for terahertz frequencies P Padhy, PK Sahu, R Jha Sensors and Actuators B: Chemical 225, 115-120, 2016 | 23 | 2016 |
| Microparticle transport along a planar electrode array using moving dielectrophoresis MA Zaman, P Padhy, W Ren, M Wu, L Hesselink Journal of Applied Physics 130 (3), 2021 | 20 | 2021 |
| Controlled transport of individual microparticles using dielectrophoresis MA Zaman, P Padhy, M Wu, W Ren, MA Jensen, RW Davis, L Hesselink Langmuir 39 (1), 101-110, 2022 | 19 | 2022 |
| Extracting the potential-well of a near-field optical trap using the Helmholtz-Hodge decomposition MA Zaman, P Padhy, PC Hansen, L Hesselink Applied Physics Letters 112 (9), 2018 | 18 | 2018 |
| Optoelectronic tweezers with a non-uniform background field MA Zaman, P Padhy, YT Cheng, L Galambos, L Hesselink Applied Physics Letters 117 (17), 2020 | 17 | 2020 |
| On the substrate contribution to the back action trapping of plasmonic nanoparticles on resonant near-field traps in plasmonic films P Padhy, MA Zaman, P Hansen, L Hesselink Optics Express 25 (21), 26198-26214, 2017 | 16 | 2017 |
| Capturing range of a near-field optical trap MA Zaman, P Padhy, L Hesselink Physical Review A 96 (4), 043825, 2017 | 15 | 2017 |
| Modeling brownian microparticle trajectories in lab-on-a-chip devices with time varying dielectrophoretic or optical forces MA Zaman, M Wu, P Padhy, MA Jensen, L Hesselink, RW Davis Micromachines 12 (10), 1265, 2021 | 13 | 2021 |
| Fokker-Planck analysis of optical near-field traps MA Zaman, P Padhy, L Hesselink Scientific Reports 9 (1), 9557, 2019 | 11 | 2019 |
| Dynamically controlled dielectrophoresis using resonant tuning P Padhy, MA Zaman, MA Jensen, L Hesselink Electrophoresis 42 (9-10), 1079-1092, 2021 | 7 | 2021 |
| In-plane near-field optical barrier on a chip P Padhy, MA Zaman, L Hesselink Optics letters 44 (8), 2061-2064, 2019 | 7 | 2019 |
| THz mode-coupling in photonic-crystal–surface-plasmon-coupled waveguides T Srivastava, R Das, P Padhy, R Jha Applied Physics B 118, 387-392, 2015 | 4 | 2015 |
| A semi-analytical model of a near-field optical trapping potential well MA Zaman, P Padhy, L Hesselink Journal of Applied Physics 122 (16), 2017 | 3 | 2017 |
| Dielectrophoretic bead-droplet reactor for solid-phase synthesis P Padhy, MA Zaman, MA Jensen, YT Cheng, Y Huang, M Wu, ... Nature Communications 15 (1), 6159, 2024 | 2 | 2024 |
Mohammad Asif ZamanPostdoctoral scholar, Edward L. Ginzton Lab, Stanford UniversityPatvirtintas el. paštas stanford.edu