Atomistic Positioning of Defects in Helium Ion Treated Single-Layer MoS2.
Elmar MitterreiterBruno SchulerKatherine A CochraneUrsula WurstbauerAlexander Weber-BargioniChristoph KastlAlexander W HolleitnerPublished in: Nano letters (2020)
Structuring materials with atomic precision is the ultimate goal of nanotechnology and is becoming increasingly relevant as an enabling technology for quantum electronics/spintronics and quantum photonics. Here, we create atomic defects in monolayer MoS2 by helium ion (He-ion) beam lithography with a spatial fidelity approaching the single-atom limit in all three dimensions. Using low-temperature scanning tunneling microscopy (STM), we confirm the formation of individual point defects in MoS2 upon He-ion bombardment and show that defects are generated within 9 nm of the incident helium ions. Atom-specific sputtering yields are determined by analyzing the type and occurrence of defects observed in high-resolution STM images and compared with Monte Carlo simulations. Both theory and experiment indicate that the He-ion bombardment predominantly generates sulfur vacancies.
Keyphrases
- monte carlo
- high resolution
- molecular dynamics
- quantum dots
- room temperature
- electron microscopy
- reduced graphene oxide
- deep learning
- cardiovascular disease
- risk assessment
- optical coherence tomography
- high speed
- photodynamic therapy
- type diabetes
- mass spectrometry
- machine learning
- highly efficient
- high throughput
- gold nanoparticles
- energy transfer