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1. Intrinsic donor-bound excitons in ultraclean monolayer semiconductors

   https://doi.org/10.1038/s41467-021-21158-8  

   Rivera, Pasqual; He, Minhao; Kim, Bumho; Liu, Song; Rubio-Verdú, Carmen; Moon, Hyowon; Mennel, Lukas; Rhodes, Daniel A.; Yu, Hongyi; Taniguchi, Takashi; et al (December 2021, Nature Communications)

   null (Ed.)

   Abstract The monolayer transition metal dichalcogenides are an emergent semiconductor platform exhibiting rich excitonic physics with coupled spin-valley degree of freedom and optical addressability. Here, we report a new series of low energy excitonic emission lines in the photoluminescence spectrum of ultraclean monolayer WSe 2 . These excitonic satellites are composed of three major peaks with energy separations matching known phonons, and appear only with electron doping. They possess homogenous spatial and spectral distribution, strong power saturation, and anomalously long population (>6 µs) and polarization lifetimes (>100 ns). Resonant excitation of the free inter- and intravalley bright trions leads to opposite optical orientation of the satellites, while excitation of the free dark trion resonance suppresses the satellitesʼ photoluminescence. Defect-controlled crystal synthesis and scanning tunneling microscopy measurements provide corroboration that these features are dark excitons bound to dilute donors, along with associated phonon replicas. Our work opens opportunities to engineer homogenous single emitters and explore collective quantum optical phenomena using intrinsic donor-bound excitons in ultraclean 2D semiconductors. 

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2. Long-range transport of 2D excitons with acoustic waves

   https://doi.org/10.1038/s41467-022-29042-9  

   Peng, Ruoming; Ripin, Adina; Ye, Yusen; Zhu, Jiayi; Wu, Changming; Lee, Seokhyeong; Li, Huan; Taniguchi, Takashi; Watanabe, Kenji; Cao, Ting; et al (December 2022, Nature Communications)

   Abstract Excitons are elementary optical excitation in semiconductors. The ability to manipulate and transport these quasiparticles would enable excitonic circuits and devices for quantum photonic technologies. Recently, interlayer excitons in 2D semiconductors have emerged as a promising candidate for engineering excitonic devices due to their long lifetime, large exciton binding energy, and gate tunability. However, the charge-neutral nature of the excitons leads to weak response to the in-plane electric field and thus inhibits transport beyond the diffusion length. Here, we demonstrate the directional transport of interlayer excitons in bilayer WSe 2 driven by the propagating potential traps induced by surface acoustic waves (SAW). We show that at 100 K, the SAW-driven excitonic transport is activated above a threshold acoustic power and reaches 20 μm, a distance at least ten times longer than the diffusion length and only limited by the device size. Temperature-dependent measurement reveals the transition from the diffusion-limited regime at low temperature to the acoustic field-driven regime at elevated temperature. Our work shows that acoustic waves are an effective, contact-free means to control exciton dynamics and transport, promising for realizing 2D materials-based excitonic devices such as exciton transistors, switches, and transducers up to room temperature. 

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3. Quasi-1D exciton channels in strain-engineered 2D materials

   https://doi.org/10.1126/sciadv.abj3066  

   Dirnberger, Florian; Ziegler, Jonas D.; Faria Junior, Paulo E.; Bushati, Rezlind; Taniguchi, Takashi; Watanabe, Kenji; Fabian, Jaroslav; Bougeard, Dominique; Chernikov, Alexey; Menon, Vinod M. (October 2021, Science Advances)

   Strain engineering is a powerful tool in designing artificial platforms for high-temperature excitonic quantum devices. Combining strong light-matter interaction with robust and mobile exciton quasiparticles, two-dimensional transition metal dichalcogenides (2D TMDCs) hold great promise in this endeavor. However, realizing complex excitonic architectures based on strain-induced electronic potentials alone has proven to be exceptionally difficult so far. Here, we demonstrate deterministic strain engineering of both single-particle electronic bandstructure and excitonic many-particle interactions. We create quasi-1D transport channels to confine excitons and simultaneously enhance their mobility through locally suppressed exciton-phonon scattering. Using ultrafast, all-optical injection and time-resolved readout, we realize highly directional exciton flow with up to 100% anisotropy both at cryogenic and room temperatures. The demonstrated fundamental modification of the exciton transport properties in a deterministically strained 2D material with effectively tunable dimensionality has broad implications for both basic solid-state science and emerging technologies. 

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4. Spin wavepackets in the Kagome ferromagnet Fe ₃ Sn ₂ : Propagation and precursors

   https://doi.org/10.1073/pnas.2220589120  

   Lee, Changmin; Sun, Yue; Ye, Linda; Rathi, Sumedh; Wang, Kevin; Lu, Yuan-Ming; Moore, Joel; Checkelsky, Joseph G.; Orenstein, Joseph (May 2023, Proceedings of the National Academy of Sciences)

   The propagation of spin waves in magnetically ordered systems has emerged as a potential means to shuttle quantum information over large distances. Conventionally, the arrival time of a spin wavepacket at a distance,d, is assumed to be determined by its group velocity,v_g. Here, we report time-resolved optical measurements of wavepacket propagation in the Kagome ferromagnet Fe₃Sn₂that demonstrate the arrival of spin information at times significantly less thand/v_g. We show that this spin wave “precursor” originates from the interaction of light with the unusual spectrum of magnetostatic modes in Fe₃Sn₂. Related effects may have far-reaching consequences toward realizing long-range, ultrafast spin wave transport in both ferromagnetic and antiferromagnetic systems. 

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5. Controlling exciton transport in monolayer MoSe ₂ by dielectric screening

   https://doi.org/10.1039/C9NH00462A  

   Hao, Shengcai; Bellus, Matthew Z.; He, Dawei; Wang, Yongsheng; Zhao, Hui (January 2020, Nanoscale Horizons)

   Due to their atomic thinness with reduced dielectric screening, two-dimensional materials can possess a stable excitonic population at room temperature. This is attractive for future excitonic devices, where excitons are used to carry energy or information. In excitonic devices, controlling transport of the charge-neutral excitons is a key element. Here we show that exciton transport in a MoSe 2 monolayer semiconductor can be effectively controlled by dielectric screening. A MoSe 2 monolayer was partially covered with a hexagonal boron nitride flake. Photoluminescence measurements showed that the exciton energy in the covered region is about 12 meV higher than that in the uncovered region. Spatiotemporally resolved differential reflection measurements performed at the junction between the two regions revealed that this energy offset is sufficient to drive excitons across the junction for about 50 ps over a distance of about 200 nm. These results illustrate the feasibility of using van der Waals dielectric engineering to control exciton transport and contribute to understanding the effects of the dielectric environment on the electronic and optical properties of two-dimensional semiconductors. 

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