<i>Colloquium</i>
: Excitons in atomically thin transition metal dichalcogenides

Wang, Gang; Chernikov, Alexey; Glazov, M. M.; Heinz, Tony F.; Marie, X.; Amand, T.; Urbaszek, B.

doi:10.1103/revmodphys.90.021001

Cited by 1,634 publications

(1,684 citation statements)

References 280 publications

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“…In recent years, excitons—i.e., electron–hole pairs bounded through their mutual Coulomb interaction—in 2D materials like TMDCs have attracted a great deal of attention due to their singular optical properties . These, to a great extent, reflect the presence of 2D excitons with large binding energies (hundreds of meV), thereby making such collective excitations stable even at room temperature.…”

Section: Strong Light–matter Interactions In Layered Transition Metalmentioning

confidence: 99%

“…This is in stark contrast with excitons in conventional bulk 3D semiconductors which typically possess binding energies of the order of

k_{B} T

(where

k_{B} T ≃ 26 meV

at T = 300 K). The reason for this order‐of‐magnitude difference lies in inherently reduced screening in two dimensions …”

Section: Strong Light–matter Interactions In Layered Transition Metalmentioning

confidence: 99%

“…As the low‐energy physics of atomically thin TMDCs is well‐described by an effective Dirac‐like Hamiltonian with finite mass, the valley degree of freedom can be used to manipulate the spin polarization of electrons—due to the sizable spin‐orbit coupling exhibited by such materials—using circularly polarized light . Pioneering experiments have shown that it is possible to inject excitons with highly polarized spins that could be utilized for valleytronics .…”

Section: Strong Light–matter Interactions In Layered Transition Metalmentioning

confidence: 99%

See 2 more Smart Citations

Strong Light–Matter Interactions Enabled by Polaritons in Atomically Thin Materials

Gonçalves

Stenger

Cox

et al. 2020

Advanced Optical Materials

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Polaritons, resulting from the hybridization of light with polarization charges formed at the boundaries between media with positive and negative dielectric response functions, can focus light into regions much smaller than its associated free‐space wavelength. This property is paramount for a plethora of applications in nanophotonics, ranging from biological sensing to photocatalysis to nonlinear and quantum optics. In the two‐dimensional (2D) limit, represented by atomically thin and van der Waals (vdW) materials of single‐layers bound by weak vdW attraction, polaritons are characterized by extremely small wavelengths associated with extreme optical confinement, and furthermore can exhibit long lifetimes, electrical tunability, and extreme sensitivity to their dielectric environment, among many other desirable qualities in nano‐optical device applications. Here, the fundamentals of polaritons in atomically thin materials are summarized, emphasizing plasmon and exciton polaritons, their strong light–matter interactions, and nonlinear plasmonics. More specifically, this review opens with a pedagogical discussion of plasmons in extended and nanostructured graphene, providing a classical electrodynamical model in a nonretarded theoretical framework, and the ultraconfined acoustic plasmons supported by hybrid graphene–dielectric–metal structures. In addition, the basic principles are introduced and the recent developments on nonlinear graphene plasmonics and on strong coupling physics with atomically thin transition metal dichalcogenides are reviewed. Finally, potentially new, promising research directions in the burgeoning field of 2D nanophotonics are identified.

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Section: Strong Light–matter Interactions In Layered Transition Metalmentioning

confidence: 99%

“…This is in stark contrast with excitons in conventional bulk 3D semiconductors which typically possess binding energies of the order of

k_{B} T

(where

k_{B} T ≃ 26 meV

at T = 300 K). The reason for this order‐of‐magnitude difference lies in inherently reduced screening in two dimensions …”

Section: Strong Light–matter Interactions In Layered Transition Metalmentioning

confidence: 99%

Section: Strong Light–matter Interactions In Layered Transition Metalmentioning

confidence: 99%

See 1 more Smart Citation

Strong Light–Matter Interactions Enabled by Polaritons in Atomically Thin Materials

Gonçalves

Stenger

Cox

et al. 2020

Advanced Optical Materials

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“…The valley Hall effect in monolayer TMDCs is closely related to valley circular dichroism,84,85 where the carriers give rise to opposite Hall currents in opposite valleys 86–88. Under the illumination of circularly polarized light and an in‐plane electric field, populations of carriers with opposite signs will accumulate in +K and −K valleys of monolayer TMDCs, respectively, as shown in Figure 2a.…”

Section: Valley Excitons and Pseudospins In 2d Tmdcsmentioning

confidence: 99%

“…In early studies, it was observed that PL polarization retention is independent of the substrate 9. It approaches unity at low temperature9,85 but is significantly lower (≈40% for monolayer MoS 2 and ≈10% for WS 2 ) at RT 85–87. Later in 2016, Nayak et al reported a world record of valley polarization contrast of 35% for monolayer WS 2 , achieved by using near‐resonant below‐bandgap excitation and chemical vapor deposition (CVD) grown monolayer WS 2 92.…”

Section: Valley Excitons and Pseudospins In 2d Tmdcsmentioning

confidence: 99%

Chiral Coupling of Valley Excitons and Light through Photonic Spin–Orbit Interactions

Chen

Fan

et al. 2019

Advanced Optical Materials

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Spintronics employs the spin of electrons to encode information. Akin to spintronics, valleytronics exploits the valley as pseudospin‐carrying controllable binary information. 2D transition metal dichalcogenides (TMDCs) have asymmetric +K and −K valleys. The valley pseudospins of these materials can be manipulated by selective pumping, giving rise to valley‐dependent circularly polarized photoluminescence. The photonic spin–orbit interactions (SOIs) in nanophotonic systems allow the transformation or coupling of optical spin angular momentum to orbital angular momentum of light. Hybridizing 2D TMDC electronic systems with nanophotonic systems can open up an avenue for merging TMDC valley polarization and photonic SOIs to uncover new mechanisms of on‐chip optical information processing and transport. This review focuses on the fundamentals and implications of TMDC valley polarization, photonic SOI effects, and their chiral coupling in hybrid TMDCs–nanophotonic systems. First, the deterministic valley‐dependent optical properties of TMDCs and recent efforts in achieving large valley polarization contrast are reviewed. Then, various SOI effects in nanophotonic systems and their physical mechanisms are summarized. At the end, recent demonstrations of chiral coupling between TMDC valley excitons and light through spin‐direction locking at hybrid interfaces are highlighted.

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Valleytronics in 2D Materials

Vitale

2023

Beyond‐CMOS

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Colloquium : Excitons in atomically thin transition metal dichalcogenides

Cited by 1,634 publications

References 280 publications

Strong Light–Matter Interactions Enabled by Polaritons in Atomically Thin Materials

Strong Light–Matter Interactions Enabled by Polaritons in Atomically Thin Materials

Chiral Coupling of Valley Excitons and Light through Photonic Spin–Orbit Interactions

Valleytronics in 2D Materials

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