Strain-Dependent Optical Properties of Monolayer WSe<sub>2</sub>

Lv, Yanhui; Abid, Mohamed; Cheng, H. H.; Coileáin, Cormac Ó; Sofin, R. G. S; Chang, Ching-Ray; Wu, Han-Chun

doi:10.1021/acs.jpcc.3c06393

Cited by 4 publications

(1 citation statement)

References 74 publications

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“…On the other hand, enhancement of the valley polarization of WSe 2 monolayer excitons has been pursued using techniques such as optical pumping, magnetic fields, electrical fields, ,− strain, defects, , and the formation of heterojunctions . Recent advances have demonstrated that site-controlled quantum emission from specific excitons, particularly enhanced emission from dark excitons, can be achieved using templates with prepatterned nanostructures . Furthermore, the valley polarization of bright excitons can be influenced by an yttrium iron garnet (YIG) substrate through the magnetic proximity effect. − Therefore, it is appealing to pose the following questions: Is it possible to simultaneously attain robust emission and elevated valley polarization of dark excitons using a prepatterned nanostructured YIG template?…”

Section: Introductionmentioning

confidence: 99%

Simultaneously Enhanced Emission and Valley Polarization of Dark Excitons of Monolayer WSe₂ Using the Dual Effect of Strain and Magnetic Proximity

Ren,

Yang,

Wang

et al. 2024

J. Phys. Chem. C

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Monolayer WSe 2 exhibits an interesting dark exciton ground state and remarkable valley properties due to broken inversion symmetry and spin−orbit coupling; such features mean WSe 2 holds significant promise for novel valleytronic devices. However, the exploitation of dark excitons in valleytronic devices is still in its infancy as it remains a challenge to achieve insensitive emission or/and high valley polarization of dark excitons. In this work, using a patterned yttrium iron garnet (YIG) substrate, we investigated the effects of magnetic proximity and strain on the optical properties of monolayer WSe 2 . It is found that with just strain the emission from dark excitons can be enhanced but with nearly zero valley polarization. The magnetic exchange interaction between YIG and single-layer WSe 2 can enhance the valley polarization of exciton emissions of monolayer WSe 2 , but the emission from dark excitons is very low. Interestingly, under the dual effect of strain and YIG magnetic proximity, the emission and valley polarization of dark excitons can be simultaneously and significantly enhanced. The intensity differences in emission excited by left and right circularly polarized light of excited dark excitons, both dark exciton (X D ) and dark trion (X DT ), are enhanced by more than a factor of 15 compared with only magnetic proximity effects. Moreover, the emission and the valley polarization of intervalley excitons were also enhanced, and valley polarization of intervalley excitons reaches 18%.

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Section: Introductionmentioning

confidence: 99%

Simultaneously Enhanced Emission and Valley Polarization of Dark Excitons of Monolayer WSe₂ Using the Dual Effect of Strain and Magnetic Proximity

Ren,

Yang,

Wang

et al. 2024

J. Phys. Chem. C

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Achieving Giant Linear Optical Response Tunability in Monolayer GeSe for Advanced Strain Sensor Applications

Chao,

Xue,

et al. 2024

ACS Appl. Electron. Mater.

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Two-dimensional (2D) layered nanomaterials with exceptional flexibility offer a promising platform for the development of advanced microstrain sensors. Herein, we meticulously examined the linear optical response of monolayer GeSe subjected to a spectrum of strains, spanning from −3 to 3%, encompassing both uniaxial and biaxial strain configurations, to uncover the strain-sensing capabilities of monolayer GeSe. Focusing on the perspective of the energy difference between the conduction and valence bands at high-symmetry points, we observed a significant strain-induced variation in transition energy, with sensitivities reaching up to 152.14 meV/% under biaxial strain. The transition energies demonstrate a near-perfect linear correlation with the applied strain, highlighting a highly predictable and reliable strain response. This pronounced strain-responsive behavior is attributed to the intricate interplay between orbital overlap and geometric modifications. In the context of light-field coupling with monolayer GeSe, the 1.6 eV absorption peak within the linear optical dispersion spectrum is observed to blueshift with increasing biaxial strain and uniaxial strain along the a-axis, contrastingly redshifting with uniaxial strain along the b-axis. These findings reveal that the magnitude of strain can be discerned by resolving the displacement of the linear optical absorption peaks, thereby laying a robust theoretical foundation for the engineering of monolayer GeSe-based strain sensors.

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Single-Particle Fluorescence Spectroscopy for Elucidating Charge Transfer and Catalytic Mechanisms on Nanophotocatalysts

Lv,

Zhang,

et al. 2024

ACS Nano

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Photocatalysis is a cost-effective approach to producing renewable energy. A thorough comprehension of carrier separation at the micronano level is crucial for enhancing the photochemical conversion capabilities of photocatalysts. However, the heterogeneity of photocatalyst nanoparticles and complex charge migration processes limit the profound understanding of photocatalytic reaction mechanisms. By establishing the precise interrelationship between microscopic properties and photophysical behaviors of photocatalysts, single-particle fluorescence spectroscopy can elucidate the carrier separation and catalytic mechanism of the photocatalysts in situ, which provides perspectives for improving the photocatalytic efficiency. This Review primarily focuses on the basic principles and advantages of single-particle fluorescence spectroscopy and its progress in the study of plasmonic and semiconductor photocatalysis, especially emphasizing its importance in understanding the charge separation and photocatalytic reaction mechanism, which offers scientific guidance for designing efficient photocatalytic systems. Finally, we summarize and forecast the future development prospects of single-particle fluorescence spectroscopy technology, especially the insights into its technological upgrading.

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Strain-Dependent Optical Properties of Monolayer WSe₂

Cited by 4 publications

References 74 publications

Simultaneously Enhanced Emission and Valley Polarization of Dark Excitons of Monolayer WSe₂ Using the Dual Effect of Strain and Magnetic Proximity

Simultaneously Enhanced Emission and Valley Polarization of Dark Excitons of Monolayer WSe₂ Using the Dual Effect of Strain and Magnetic Proximity

Achieving Giant Linear Optical Response Tunability in Monolayer GeSe for Advanced Strain Sensor Applications

Single-Particle Fluorescence Spectroscopy for Elucidating Charge Transfer and Catalytic Mechanisms on Nanophotocatalysts

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Strain-Dependent Optical Properties of Monolayer WSe2

Cited by 4 publications

References 74 publications

Simultaneously Enhanced Emission and Valley Polarization of Dark Excitons of Monolayer WSe2 Using the Dual Effect of Strain and Magnetic Proximity

Simultaneously Enhanced Emission and Valley Polarization of Dark Excitons of Monolayer WSe2 Using the Dual Effect of Strain and Magnetic Proximity

Achieving Giant Linear Optical Response Tunability in Monolayer GeSe for Advanced Strain Sensor Applications

Single-Particle Fluorescence Spectroscopy for Elucidating Charge Transfer and Catalytic Mechanisms on Nanophotocatalysts

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Product

Resources

About

Strain-Dependent Optical Properties of Monolayer WSe₂

Simultaneously Enhanced Emission and Valley Polarization of Dark Excitons of Monolayer WSe₂ Using the Dual Effect of Strain and Magnetic Proximity

Simultaneously Enhanced Emission and Valley Polarization of Dark Excitons of Monolayer WSe₂ Using the Dual Effect of Strain and Magnetic Proximity