First-principles insights into the spin-valley physics of strained transition metal dichalcogenides monolayers
Transition metal dichalcogenides (TMDCs) are ideal candidates to explore the manifestation of spin-valley physics under external stimuli. In this study, we investigate the influence of strain on the spin and orbital angular momenta, effective g -factors, and Berry curvatures of several monolayer TMD...
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Veröffentlicht in: | New journal of physics 2022-08, Vol.24 (8), p.83004 |
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Sprache: | eng |
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Zusammenfassung: | Transition metal dichalcogenides (TMDCs) are ideal candidates to explore the manifestation of spin-valley physics under external stimuli. In this study, we investigate the influence of strain on the spin and orbital angular momenta, effective
g
-factors, and Berry curvatures of several monolayer TMDCs (Mo and W based) using a full
ab initio
approach. At the
K
-valleys, we find a surprising decrease of the conduction band spin expectation value for compressive strain, consequently increasing the dipole strength of the dark exciton by more than one order of magnitude (for
∼
1
%
–
2
%
strain variation). We also predict the behavior of direct excitons
g
-factors under strain: tensile (compressive) strain increases (decreases) the absolute value of
g
-factors. Strain variations of ∼1% modify the bright (A and B) excitons
g
-factors by ∼0.3 (0.2) for W (Mo) based compounds and the dark exciton
g
-factors by ∼0.5 (0.3) for W (Mo) compounds. Our predictions could be directly visualized in magneto-optical experiments in strained samples at low temperature. Additionally, our calculations strongly suggest that strain effects are one of the possible causes of
g
-factor fluctuations observed experimentally. By comparing the different TMDC compounds, we reveal the role of spin–orbit coupling (SOC): the stronger the SOC, the more sensitive are the spin-valley features under applied strain. Consequently, monolayer WSe
2
is a formidable candidate to explore the role of strain on the spin-valley physics. We complete our analysis by considering the side valleys, Γ and
Q
points, and by investigating the influence of strain in the Berry curvature. In the broader context of valley- and strain-tronics, our study provides fundamental microscopic insights into the role of strain in the spin-valley physics of TMDCs, which are relevant to interpret experimental data in monolayer TMDCs as well as TMDC-based van der Waals heterostructures. |
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ISSN: | 1367-2630 1367-2630 |
DOI: | 10.1088/1367-2630/ac7e21 |