Electronic and Structural Properties of Lanthanide-Doped MoS2: Impact of Ionic Size and Orbital Configuration Mismatch
Abstract
Single-photon emitters (SPEs) are crucial for quantum technologies such as quantum simulation, secure quantum communication, and precision measurements. Two-dimensional transition metal dichalcogenides (TMDCs) are promising SPE candidates due to their atomically thin nature and efficient photon extraction. However, their emission wavelengths limit compatibility with existing telecommunication technologies. Lanthanide doping in TMDCs, such as MoS2, offers a potential solution by introducing sharp, f-orbital derived emissions in the infrared range. Yet, the feasibility of introducing these dopants remains uncertain due to their large ionic radii of the lanthanides. We employ density functional theory (DFT) calculations to investigate the structural and electronic properties of lanthanide-doped MoS2 monolayers (Ln=Ce, Er). By evaluating formation energies with up to three adjacent S vacancies, we assess how these vacancies mitigate lattice strain caused by the size mismatch of Ce and Er with Mo. Our results show that while LnMo destabilizes the pristine lattice, S vacancies enhance thermodynamic stability. Charge state analysis indicates that defect states introduced by LnMo localize near the valence band and remain stable across a wide Fermi energy range. Electronic structure analysis shows that Ce4+ and Er3+ maintain their oxidation states upon electron doping due to additional acceptor states from host-induced dangling bonds. These states arise from an orbital filling mismatch between dopants and Mo. Consequently, CeMo is unlikely to exhibit infrared emissions due to its empty f-shell, whereas ErMo is expected to emit in the infrared. These findings demonstrate the potential of lanthanide-doped TMDCs as tunable SPEs and provide design strategies for optimizing their optical and electronic properties.
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