AI Article Synopsis
- - The study calculates the interband optical absorption spectrum of silicon using first principles, focusing on quasiparticle levels and employing Wannier interpolation for precision.
- - Their findings for indirect absorption closely match experimental results across different temperatures, confirming the method's accuracy.
- - The approach effectively analyzes silicon's optical absorption spectrum in the visible range, which is crucial for optoelectronic and photovoltaic technologies, and can be applied to other materials as well.
Article Abstract
The phonon-assisted interband optical absorption spectrum of silicon is calculated at the quasiparticle level entirely from first principles. We make use of the Wannier interpolation formalism to determine the quasiparticle energies, as well as the optical transition and electron-phonon coupling matrix elements, on fine grids in the Brillouin zone. The calculated spectrum near the onset of indirect absorption is in very good agreement with experimental measurements for a range of temperatures. Moreover, our method can accurately determine the optical absorption spectrum of silicon in the visible range, an important process for optoelectronic and photovoltaic applications that cannot be addressed with simple models. The computational formalism is quite general and can be used to understand the phonon-assisted absorption processes in general.
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| http://dx.doi.org/10.1103/PhysRevLett.108.167402 | DOI Listing |
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