1. Laser-Assisted Scalable Pore Fabrication in Graphene Membrane for Blue Energy Generation, Sharad Kumar Yadav, D Manikandan, Chob Singh, Mukesh Kumar, G. Aswathy, Ramaprabhu Sundara, Vishal V. R. Nandigana, Pramoda Kumar Nayak, Chemphyschem, (2023), 24, e2022005183.
2. Convolutional Neural Networks for Heat Conduction, S. Tadeparti, Vishal Nandigana, Case Studies in Thermal Engineering, (2022), 38, 102089.
3. Design and development of an automated experimental setup for ion transport measurements, Sharad Yadav, Mahesh Kumar, Sundara Ramaprabhu, Vishal Nandigana, Pramoda Nayak, Review of Scientific Instruments, (2022), 93, 064104.
4. Electrodiffusioosmosis induced negative differential resistance in micro-to-millimeter size pores through a graphene/copper membrane, Sharad Kumar Yadav, D. Manikandan, Chob Singh, Mukesh Kumar, Vishal V. R. Nandigana, Pramoda K Nayak, Nanoscale Advances, (2022), 4, 5123-5131.
5. Overlimiting current near a nanochannel a new insight using molecular dynamics simulations, D. Manikandan, Vishal Nandigana, Scientific Reports, (2021), 11, 15216.
6. A molecular dynamics simulation framework for predicting noise in solid-state nanopores, Onkar Patil, D. Manikandan, Vishal Nandigana, Molecular Simulation, (2020), 46, 1011-1016 .
7. 2D materials as an emerging platform for nanopore-based power generation, Michal Macha, Sanjin Marion, Vishal V. R. Nandigana, Aleksandra Radenovic, Nature Rev. Materials, (2019), 4, 588-605.
8. Asymmetric-fluidic-reservoirs induced high rectification nanofluidic diode, Vishal V, . R. Nandigana, Kyoo Jo, Aaron Timperman, Narayana R Aluru, Scientific reports, (2018), 8, 13941.
9. 1/f pink chaos in nanopores, Vishal V. R. Nandigana, N. R. Aluru, RSC advances, (2017), 7, 46092-46100.
10. Single-layer MoS2 nanopores as nanopower generators, Jiandong Feng, Michael Graf, Ke Liu, Dmitry Ovchinnikov, Dumitru Dumcenco, Mohammad Heiranian, Vishal Nandigana, Narayana R Aluru, Andras Kis, Aleksandra Radenovic, Nature, (2016), 536, 197-200.
11. Avalanche effects near nanojunctions, Vishal V. R. Nandigana, N. R. Aluru, Physical Review E, (2016), 94, 012402.
12. Controlling the ionic current rectification factor of a nanofluidic/microfluidic interface with symmetric nanocapillary interconnects, Han Wang, Vishal V. R. Nandigana, Kyoo Dong Jo, Narayana R Aluru, Aaron T Timperman, Analytical chemistry, (2015), 87, 3598-3605.
13. Mechanisms for hydrolysis of silicon nanomembranes as used in bioresorbable electronics, Lan Yin, Amir Barati Farimani, Kyoungmin Min, Nandigana Vishal, Jasper Lam, Yoon Kyeung Lee, Narayana R Aluru, John A Rogers, Adv. Mater, (2015), 27, 1857-1864.
14. Characterization of electrochemical properties of a micro–nanochannel integrated system using computational impedance spectroscopy (CIS), Vishal V. R. Nandigana, N. R. Aluru, Electrochimica Acta, (2013), 105, 514-523.
15. Nonlinear electrokinetic transport under combined ac and dc fields in micro/nanofluidic interface devices, Vishal V. R. Nandigana, N. R. Aluru, Journal of fluids engineering, (2013), 135, 021201.
16. Understanding anomalous current–voltage characteristics in microchannel–nanochannel interconnect devices, Vishal V. R. Nandigana, N. R. Aluru, Journal of colloid and interface science, (2012), 384, 162-171.
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