Neutral band gap of carbon by quantum Monte Carlo methods

Neutral band gap of carbon by quantum Monte Carlo methods

We present a method of calculating the energy gap of a charge-neutral excitation using only ground-state calculations. We report Quantum Monte Carlo calculations of Γ→ Γ and Γ → X particle-hole excitation energies in diamond carbon. We analyze the finite-size effect and find the same 1/L decay rate...

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Veröffentlicht in:Condensed matter physics 2023-01, Vol.26 (3), p.33701
Hauptverfasser: Gorelov, V., Yang, Y., Ruggeri, M., Ceperley, D. M., Pierleoni, C., Holzmann, M.
Format: Artikel
Sprache:eng
Schlagworte:
band gap
diamond
electronic structure
Energy Gap
excitons
first-principles calculations
MATERIALS SCIENCE
Physics
Quantum Monte Carlo
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Zusammenfassung:We present a method of calculating the energy gap of a charge-neutral excitation using only ground-state calculations. We report Quantum Monte Carlo calculations of Γ→ Γ and Γ → X particle-hole excitation energies in diamond carbon. We analyze the finite-size effect and find the same 1/L decay rate as that in a charged excitation, where L is the linear extension of the supercell. This slow decay is attributed to the delocalized nature of the excitation in supercells too small to accommodate excitonic binding effects. At larger system sizes, the apparent 1/L decay crosses over to a 1/L3 behavior. Estimation of the scale of exciton binding can be used to correct finite-size effects of neutral gaps.
ISSN:1607-324X
2224-9079
DOI:10.5488/CMP.26.33701