Abstract
The convenient graphical user-interfaces now available with advanced simulation software offer a powerful didactic tool for research-led teaching of methods in quantum chemistry and wider applications of quantum mechanics. In the student project work reported here, a homologous series of semiconducting chalcogenophenes (encompassing poly-thiophenes, poly-selenophenes and poly-tellurophenes) with varying polymer chain lengths were simulated in detail using density functional theory (DFT). Following geometry optimization, energy calculations reveal that increasing the length of the polymer chain (N) from a monomer to a hexamer leads to a narrowing and large-N convergence of the bandgap. It is found that hexa-tellurophene has significantly favourable electronic properties as compared to the other analogues, with a greatly enhanced electron affinity (−2.74 eV), and a corresponding bandgap energy of 2.18 eV, giving a superior matching to the solar spectrum.
Original language | English |
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Article number | 025401 |
Number of pages | 13 |
Journal | European Journal of Physics |
Volume | 44 |
Issue number | 2 |
DOIs | |
Publication status | Published - 02 Mar 2023 |
Keywords
- Paper
- Quantum physics and quantum mechanics
- simulation
- graphical user-interface
- quantum chemistry
- semiconductors
- chalcogenophenes
- undergraduate projects
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Supporting data for "Quantum Chemistry Simulations in an Undergraduate Project: Tellurophenes as Narrow Bandgap Semiconductor Materials"
Walker, B. & Finlayson, C., Prifysgol Aberystwyth | Aberystwyth University, 06 Mar 2023
DOI: 10.20391/bf829ddb-2da8-45dd-9e2e-27478075bd0c
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