Signatures of Electric Field and Layer Separation Effects on the Spin-Valley Physics of MoSe2/WSe2 Heterobilayers: From Energy Bands to Dipolar Excitons

Abstract: Multilayered van der Waals heterostructures based on transition metal dichalcogenides are suitable platforms on which to study interlayer (dipolar) excitons, in which electrons and holes are localized in different layers. Interestingly, these excitonic complexes exhibit pronounced valley Zeeman signatures, but how their spin-valley physics can be further altered due to external parameters—such as electric field and interlayer separation—remains largely unexplored. Here, we perform a systematic analysis of the … Show more

“…These distinct g -factors provide valuable insights into the intricate interplay between electronic and magnetic degrees of freedom, underscoring the importance of considering the magnetic state of CrSBr in understanding the behavior of excitonic systems in this heterostructure. The changes in the magnitude of the g -factors are consistent with proximity effects due to the hybridization between the layers, as previously demonstrated in MoSe 2 /WSe 2 , , WSe 2 /CrI 3 , and WS 2 /graphene systems . A systematic analysis of the microscopic features behind the asymmetric g -factors is beyond the scope of the current manuscript; however, we point out that asymmetric signatures in valley Zeeman splitting have recently been observed in MoSe 2 /CrBr 3 heterostructures at zero magnetic field.…”

Charge Transfer and Asymmetric Coupling of MoSe₂ Valleys to the Magnetic Order of CrSBr

“…These distinct g -factors provide valuable insights into the intricate interplay between electronic and magnetic degrees of freedom, underscoring the importance of considering the magnetic state of CrSBr in understanding the behavior of excitonic systems in this heterostructure. The changes in the magnitude of the g -factors are consistent with proximity effects due to the hybridization between the layers, as previously demonstrated in MoSe 2 /WSe 2 , , WSe 2 /CrI 3 , and WS 2 /graphene systems . A systematic analysis of the microscopic features behind the asymmetric g -factors is beyond the scope of the current manuscript; however, we point out that asymmetric signatures in valley Zeeman splitting have recently been observed in MoSe 2 /CrBr 3 heterostructures at zero magnetic field.…”

Charge Transfer and Asymmetric Coupling of MoSe₂ Valleys to the Magnetic Order of CrSBr

“…We employed ab initio calculations for theoretical estimates of the exciton g -factor in monolayer MoTe 2 and moiré excitons in MoTe 2 –MoSe 2 heterostructures. − For the fundamental exciton X A in monolayer MoTe 2 , we obtained g A = −4.6 from g normalA = 2 ( L c − L v ) with the orbital angular momenta of the lowest conduction band and the highest valence band L c and L v . For moiré excitons, we decompose the g -factors into the individual contributions of interlayer and intralayer excitons according to hybridization-induced admixing as g i ( R ) = 2 false( 0.0ex0.0ex0.1em f i 0.0ex0.0ex0.1em false( normalX false) L c + f i 0.0ex0.0ex0.1em false( normalI normalX false) L c false′ − L v false) g i false( normalH false) = 2 ( f i ( X ) L c − f i ( I X )…”

“…with the orbital angular momenta of the lowest conduction band and the highest valence band L c and L v . For moireé xcitons, we decompose the g-factors into the individual contributions of interlayer and intralayer excitons 33 according to hybridization-induced admixing as…”

“…We employed ab initio calculations for theoretical estimates of the exciton g -factor in monolayer MoTe 2 and moiré excitons in MoTe 2 –MoSe 2 heterostructures. − For the fundamental exciton X A in monolayer MoTe 2 , we obtained g A = −4.6 from with the orbital angular momenta of the lowest conduction band and the highest valence band L c and L v . For moiré excitons, we decompose the g -factors into the individual contributions of interlayer and intralayer excitons according to hybridization-induced admixing as where i = 1, 2 indicates the hybrid X i exciton, L c ′( c ′+1) is the first (second) conduction band in the MoSe 2 layer as shown in the insets of Figure a and b, and f i (X) ( f i (IX) ) is the fraction of X (IX) exciton. Using the calculated values of the orbital angular momenta in Table S2 and the respective exciton fractions deduced from our effective model, we obtain g 1 (R) = −4.2 and g 2 (R) = −4.4 for X 1 and X 2 moiré excitons in heterostacks with a 2° twist, as well as g 1 (H) = −8.0 and g 2 (H) = −6.8 in stacks with a 58° twist angle.…”

Hybrid Moiré Excitons and Trions in Twisted MoTe₂–MoSe₂ Heterobilayers

“…The purpose of this Special Issue entitled "Excitons and Phonons in Two-Dimensional Materials: From Fundamental to Applications" is to provide a unique international forum and to cover the entire range of fundamental and applied research associated with excitonic complexes and phonon modes in two-dimensional layered materials. This Special Issue is composed of nine published papers [6][7][8][9][10][11][12][13][14] devoted to investigations of different 2D materials, such as S-TMDs, perovskites, and the multilayered structure of thin films, with theoretical [7,9,11,13] and experimental [10] approaches, as well as their combination [6,8,12,14].…”

Excitons and Phonons in Two-Dimensional Materials: From Fundamental to Applications