Revealing the Electronic Structure of van der Waals Antiferromagnetic NiPS3 through Synchrotron-Based μ-ARPES and Alkali Metal Dosing
Abstract
This study presents a comprehensive analysis of the band structure in NiPS3, a van der Waals layered antiferromagnet, utilizing high-resolution synchrotron-based angle-resolved photoemission spectroscopy (ARPES) and corroborative density functional theory (DFT) calculations. By tuning the parameters of the light source, we obtained a very clear and wide energy range band structure of NiPS3. Comparison with DFT calculations allows for the identification of the orbital character of the observed bands. Our DFT calculations perfectly match the experimental results, and no adaptations were made to the calculations based on the experimental outcomes. The appearance of novel electronic structure upon alkali metal dosing (AMD) were also obtained in this ARPES study. Above valence band maximum, structure of conduction bands and bands from defect states were firstly observed in NiPS3. We provide the direct determination of the band gap of NiPS3 as 1.3 eV from the band structure by AMD. In addition, detailed temperature dependent ARPES spectra were obtained across a range that spans both below and above the N\'eel transition temperature of NiPS3. We found that the paramagnetic and antiferromagnetic states have almost identical spectra, indicating the highly localized nature of Ni d states.
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