The results in this project are based on ultra-low temperature (0.4 K and 4.2 K) scanning tunneling microscopy and spectroscopy (STM/STS) for single layer TMD that are grown on bilayer graphene substrate, using molecular beam epitaxy.
In the initial stage, the researcher was involved in studying substrate effects on the superconducting properties of niobium diselenide. The results pointed towards weak interaction on graphene (and on boron nitride), which provided evidence that graphene (as a substrate) was a good candidate for studying intrinsic properties of TMDs. Further STS measurements at 340 millikelvin in Niobium diselenide showed resonances outside the superconducting gap in which the origin of these peaks has been found to arise from competing pairing instabilities based on spin fluctuations.
For a better understanding of magnetic ground state in two dimensions, the researcher has investigated bilayer heterostructure of tantalum diselenide which is known to exhibit Kondo type behavior. Through high resolution STS measurements at 340 millikelvin, it was found that the typical Kondo peak, here, was comprised of two symmetric peaks split at the fermi level. With the help of magnetic field dependent STS measurements, it was concluded that the ground state lies deep in the magnetic side of the Doniach phase diagram.
In the final part, the intrinsic properties of pure niobium diselenide and tantalum diselenide were modified by means of chemical substitution with a heterovalent impurity (an another transition metal atom). Aliovalent alloy of Mo doped Niobium diselenide, of various doping levels, has allowed to investigate the atomic scale evolution of the electronic ground state across three different phase transitions, that is, superconductor-metal, CDW and metal-semiconductor. Following this innovative approach, the researcher was able to induce superconductivity in tantalum diselenide (doped with tungsten) due to an increase of the density of states (DOS), as the Fermi surface approaches a van Hove singularity.
All results of this project have been published in reputed peer-review journals with green and gold access options. These findings have also been communicated to an international audience through conferences in a timely fashion.