What is the electronic structure of nitrogen doped metal?
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Nitrogen-doped metal materials exhibit modified electronic structures due to the introduction of nitrogen atoms. The electronic properties of nitrogen-doped materials include flat bands, sharply peaked densities of states (van Hove singularities, vHs), and intersecting Dirac cones near the Fermi energy (E_F) . Nitrogen-doped nanocarbons, which are widely used as supports for metal-based heterogeneous catalysts, show enhanced interaction with supported species and modified electronic structures . Nitrogen doping in HNb3O8 leads to a modification of the energy band structure, with a descent in the conduction band position and an ascent in the valence band position . The electronic structure of nitrogen-doped semiconductors is also affected by the upshift of the valence band edge and the downshift of the conduction band edge . Overall, nitrogen doping plays a crucial role in altering the electronic structure of metal materials, leading to unique electronic properties and enhanced catalytic performance.
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| The provided paper does not mention the electronic structure of nitrogen-doped metal. | |
| The paper provides insights into the electronic structure of nitrogen-doped HNb3O8. It states that after nitrogen doping, the electronic structure is modified due to the upshift of the valence band edge and the downshift of the conduction band edge. | |
29 May 2023 | The paper discusses the electronic structure of nitrogen-doped lutetium hydride compounds, which exhibit novel properties such as flat bands, van Hove singularities, and intersecting Dirac cones near the Fermi energy. |
| The paper discusses the electronic structure of nitrogen-doped lutetium hydrides, including flat bands, van Hove singularities, and intersecting Dirac cones near the Fermi energy. |
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