Journals

21. Naskar S., Chongsiripinyo K., Mishra S., Pal A., and Jananan A., "A generalized curvilinear solver for spherical shell Rayleigh-B´enard convection ." Geophys. J. Int., 238, 631–645  (2024). 

20. Singh J., and Pal A., "Numerical investigation of water entry of hydrophobic spheres." Fluid Dyn. Res., 56, 025505 (2024). 

19. Singh N., and Pal A., “Quantifying the turbulent mixing driven by the Faraday instability in rotating miscible fluids." Phys. of Fluids, 36, 024116 (2024).

18. Varshney G., and Pal A., "Numerical investigation of viscous-fingering in a three-dimensional cubical domain."  Phys. of Fluids., 35, 102120  (2023).

17.  Singh N., and Pal A., “The onset and saturation of Faraday Instability in miscible fluids in a rotating environment.” J. Fluid Mech., 973, A6 (2023).

16. Karmakar A., Pal A., Anil Kumar G., Bhavika, Anand V., and Tyagi M., "Deep neural network-based pulse shape discrimination of neutrons and γ -rays in organic scintillation detectors." Pramana-J. Phys. 97:157 (2023).

15. Singh P., Singh N., and Pal A., “ Hanging Droplets from Liquid Interfaces.” J. Fluid Mech., 958, A48 (2023). 

14. Naskar S, and Pal A., "Effects of kinematic and magnetic boundary conditions on the dynamics of convection-driven plane layer dynamos."  J. Fluid Mech., 951, A7 (2022).

13. Singh R.,  Pal A., and De S., "Buoyancy effects on film boiling heat transfer from a sphere at low velocities." J. Fluid Mech., 943, A5 (2022). 

12. Naskar S, and Pal A., "Direct numerical simulations of optimal thermal convection in rotating plane layer dynamos." J. Fluid Mech., 942, A37 (2022).

11. Passarella L.S., Mahajan S., Pal A., Norman M.R., "Reconstructing high-resolution ESM data through a novel Fast Super-Resolution Convolutional Neural Network (FSRCNN)." Geophy. Res. Lett., 49, e2021GL097571 (2022). 

10. Pal A., "Deep learning emulation of subgrid-scale processes in turbulent shear flows." Geophy. Res. Lett., 47(12), e2020GL087005 (2020). 

9. Pal A. and Chalamalla V. K., "Evolution of plumes and turbulent dynamics in deep ocean convection."  J. Fluid Mech. 889, A35 (2020). 

8. Pal A., Mahajan S, and Norman M. R., ”Using Deep Neural Networks as Cost-Effective Surrogate Models for GCM Radiative Transfer.” Geophy. Res. Lett. 46 (11), 6069-6079 (2019). 

7. Chongsiripinyo K., Pal A.,  and Sarkar S., ``On the vortex dynamics of flow past a sphere at Re  = 3700 in a uniformly stratified fluid." Phys. of Fluids. 29, 020704 (2017).

6. Pal A., Sarkar S., Posa A., and Balaras E,'' DNS of stratified flow past a sphere at a subcritical Reynolds number of 3700 and moderate Froude number." J. Fluid Mech. 826, 5-31. 

5. Pal A., Sarkar S., Posa A., and Balaras E., ``Regeneration of turbulent fluctuations in low-Froude number flow over a sphere at a Reynolds number of 3700." J. Fluid Mech., 804 R2 (2016). 

4. Pal A. and Sarkar S., ``Effect of external turbulence on the evolution of a wake in stratified and unstratified environments'' J. Fluid Mech., 772, 361-385 (2015). 

3. Y Bazilevs, A Korobenko, J Yan, A. Pal, S Sarkar., ``ALE-VMS formulation for stratified turbulent incompressible flows with applications,'' Mathematical Models and Methods in Applied Sciences, 25(12), 2349-2375 (2015). 

2. Pal A., deStadler M.B., and Sarkar S., ``The spatial evolution of fluctuations in a self-propelled wake compared to a patch of turbulence,''  Phys. of Fluids., 25 (9), 095106 (2013).  

1. Pal A., Bandyopadhyay D., Biswas G., and Eswaran V., ``Enhancement of heat transfer using delta-winglet type vortex generators with a common-flow-up arrangement,'' Numerical Heat Transfer, Part A: Applications., 61(12), 912-928 (2012).