Anna Nolinder scite author profile

Atomically thin semiconductors have dimensions that are commensurate with critical feature sizes of future optoelectronic devices defined using electron/ion beam lithography. Robustness of their emergent optical and valleytronic properties is essential for typical exposure doses used during fabrication. Here, we explore how focused helium ion bombardement affects the intrinsic vibrational, luminescence and valleytronic properties of atomically thin MoS2. By probing the disorder dependent vibrational response we deduce the interdefect distance by applying a phonon confinement model. We show that the increasing interdefect distance correlates with disorder-related luminscence arising 180 meV below the neutral exciton emission. We perform ab-initio density functional theory of a variety of defect related morphologies, which yield first indications on the origin of the observed additional luminescence. Remarkably, no significant reduction of free exciton valley polarization is observed until the interdefect distance approaches a few nanometers, namely the size of the free exciton Bohr radius. Our findings pave the way for direct writing of sub-10 nm nanoscale valleytronic devices and circuits using focused helium ions. arXiv:1705.01375v2 [cond-mat.mes-hall]

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Toward Plasmonic Tunnel Gaps for Nanoscale Photoemission Currents by On-Chip Laser Ablation

Zimmermann

Hötger

Fernandez

et al. 2019

Nano Lett.

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We demonstrate that prestructured metal nanogaps can be shaped on-chip to below 10 nm by femtosecond laser ablation. We explore the plasmonic properties and the nonlinear photocurrent characteristics of the formed tunnel junctions. The photocurrent can be tuned from multiphoton absorption toward the laser-induced strong-field tunneling regime in the nanogaps. We demonstrate that a unipolar ballistic electron current is achieved by designing the plasmonic junctions to be asymmetric, which allows ultrafast electronics on the nanometer scale.

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Tuning the Optical Properties of a MoSe₂ Monolayer Using Nanoscale Plasmonic Antennas

et al. 2022

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Nanoplasmonic systems combined with optically active two-dimensional materials provide intriguing opportunities to explore and control light–matter interactions at extreme subwavelength length scales approaching the exciton Bohr radius. Here, we present room- and cryogenic-temperature investigations of a MoSe2 monolayer on individual gold dipole nanoantennas. By controlling nanoantenna size, the dipolar resonance is tuned relative to the exciton achieving a total tuning of ∼130 meV. Differential reflectance measurements performed on >100 structures reveal an apparent avoided crossing between exciton and dipolar mode and an exciton–plasmon coupling constant of g = 55 meV, representing g/(ℏω X ) ≥ 3% of the transition energy. This places our hybrid system in the intermediate-coupling regime where spectra exhibit a characteristic Fano-like shape. We demonstrate active control by varying the polarization of the excitation light to programmably suppress coupling to the dipole mode. We further study the emerging optical signatures of the monolayer localized at dipole nanoantennas at 10 K.

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Anna Nolinder

Robust valley polarization of helium ion modified atomically thin MoS ₂

Toward Plasmonic Tunnel Gaps for Nanoscale Photoemission Currents by On-Chip Laser Ablation

Tuning the Optical Properties of a MoSe₂ Monolayer Using Nanoscale Plasmonic Antennas

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About

Anna Nolinder

Robust valley polarization of helium ion modified atomically thin MoS 2

Toward Plasmonic Tunnel Gaps for Nanoscale Photoemission Currents by On-Chip Laser Ablation

Tuning the Optical Properties of a MoSe2 Monolayer Using Nanoscale Plasmonic Antennas

Contact Info

Product

Resources

About

Robust valley polarization of helium ion modified atomically thin MoS ₂

Tuning the Optical Properties of a MoSe₂ Monolayer Using Nanoscale Plasmonic Antennas