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

Covers the close connection between modeling and experimental methods for studying a wide range of nanomaterials and nanostructures Focuses on practical applications and industry needs through a solid outlining of the theoretical background Includes emerging nanomaterials and their applications in spintronics and sensing