Modeling, Characterization, and Production of Nanomaterials

1. Light-effect transistors and their applications in electronic-photonic integrated circuits<br>2. Modeling metamaterials:  Planar heterostructures based on graphene, silicene, and germanene <br>3. On the electronic and electromechanical properties of vertical and lateral 2D heterostructures<br>4. Calculation of bandgaps in nanomaterials using Harbola-Sahni and van Leeuwen-Baerends potentials<br>5. Multiscale Green’s functions for modeling graphene and other Xenes<br>6. Modeling phonons in nanomaterials<br>7. Computational modeling of thermal transport in bulk and nanostructured energy materials and systems<br>8. Molecur dynamics technique of modeling with application to thermal conductivity<br>9. Green’s function for Laplace/Poisson equations-thermal conductivity of composite materials<br>10. Atomistic simulation of biological molecules interacting with nanomaterials<br>11. Carbon-based nanomaterials<br>12. Optical spectroscopy study of 2D materials<br>13. Growth and characterization of graphene, silicene, SiC, and the related nanostructures and heterostructures on silicon wafer<br>14. Raman spectroscopy and molecular simulation studies of graphitic nanomaterials<br>15. Nanoalloys and Catalytic Applications<br>16. Lower dimensional non-toxic perovskites, structure, optoelectronic properties, and applications<br>17. TEM studies of nanostructures<br>18. Nanscale imaging of 2D materials using SMM techniques<br>19. Recent advances in thermal analysis of nanoparticles: methods, models and kinetics<br>20. Impedance humidity sensors based on Metal oxide semiconductor and its mechanism