1. Optical fingerprint of non-covalently functionalized transition metal dichalcogenides
- Author
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Maja Feierabend, Gunnar Berghäuser, Andreas Knorr, and Ermin Malic
- Subjects
Condensed Matter - Materials Science ,Materials science ,Absorption spectroscopy ,Graphene ,Exciton ,Materials Science (cond-mat.mtrl-sci) ,FOS: Physical sciences ,02 engineering and technology ,Spin–orbit interaction ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,01 natural sciences ,Molecular physics ,3. Good health ,law.invention ,Dipole ,law ,0103 physical sciences ,Monolayer ,General Materials Science ,Direct and indirect band gaps ,010306 general physics ,0210 nano-technology ,Spin (physics) - Abstract
Atomically thin transition metal dichalcogenides (TMDs) hold promising potential for applications in optoelectronics. Due to their direct band gap and the extraordinarily strong Coulomb interaction, TMDs exhibit efficient light-matter coupling and tightly bound excitons. Moreover, large spin orbit coupling in combination with circular dichroism allows for spin and valley selective optical excitation. As atomically thin materials, they are very sensitive to changes in the surrounding environment. This motivates a functionalization approach, where external molecules are adsorbed to the materials surface to tailor its optical properties. Here, we apply the density matrix theory to investigate the potential of non-covalently functionalized TMDs. Considering exemplary spiropyran molecules with a strong dipole moment, we predict spectral redshifts and the appearance of an additional side peak in the absorption spectrum of functionalized TMDs. We show that the molecular characteristics, e.g. coverage, orientation and dipole moment, crucially influence the optical properties of TMDs, leaving a unique optical fingerprint in the absorption spectrum. Furthermore, we find that the molecular dipole moments open a channel for coherent intervalley coupling between the high-symmetry K and K' points which may open new possibilities for spin-valleytronics application., 6 pages, 5 figures
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