Impact of phonons and spin-orbit coupling on Auger recombination in InAs

Shen, Julie; Steiauf, Daniel; McAllister, Andrew; Shi, Guo Hai; Kioupakis, Emmanouil; Janotti, Anderson; Walle, Chris G. Van de

doi:10.1103/physrevb.100.155202

Cited by 3 publications

(1 citation statement)

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“…Previous work on AMR in InAs found that including spin-orbit coupling did not appreciably alter the AMR rate unless the splitting was large enough to form resonant states with the band gap. [22] Given that the spin-orbit splitting in silicon is significantly smaller than the band gap, we can safely omit it from our calculations in order to reduce the computational cost without suffering any severe loss of accuracy.…”

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Phonon-assisted Auger-Meitner Recombination in Silicon from First Principles

Bushick¹,

Kioupakis²

2022

Preprint

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We develop a first-principles methodology to study both the direct and phonon-assisted Auger-Meitner recombination (AMR) in indirect-gap semiconductors and apply it to investigate the microscopic origin of AMR processes in silicon. Our results are in excellent agreement with experimental measurements and show that phonon-assisted contributions dominate the recombination rate in both n-type and p-type silicon, demonstrating the critical role of phonons in enabling AMR. We also decompose the overall rates into contributions from specific phonons and electronic valleys to further elucidate the microscopic origins of AMR. Our results highlight potential pathways to modify the AMR rate in silicon via strain engineering.

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Phonon-assisted Auger-Meitner Recombination in Silicon from First Principles

Bushick¹,

Kioupakis²

2022

Preprint

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Intrinsic carrier losses in tellurium due to radiative and Auger recombinations

Hader

Liebscher

Moloney

et al. 2022

Applied Physics Letters

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Fully microscopic many-body models based on inputs from first principles density functional theory are used to calculate the carrier losses due to radiative- and Auger-recombinations in bulk tellurium. It is shown that Auger processes dominate the losses for carrier densities in the range typical for applications as lasers. The Auger loss depends crucially on how far energetically lower hole bands are detuned from the valence band edge. Values for this detuning range throughout literature from being about equal to the bandgap to being on the order of 100 meV larger than the bandgap. We find that at cryogenic temperatures of 50 K (100 K), the Auger coefficient, C, is about six (three) orders of magnitude smaller if this detuning is as in our calculations at the low end of the published values rather than at the high end where it exceeds the bandgap. At room temperature, the sensitivity is reduced to about a factor of four with C values ranging between 0.4 and [Formula: see text] cm6 s−1. Here, radiative losses dominate for carrier densities up to about [Formula: see text] cm3 with a loss coefficient [Formula: see text] cm3 s−1. The radiative losses are about two to three times lower than in typical bulk III–V materials for comparable wavelengths.

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Phonon-Assisted Auger-Meitner Recombination in Silicon from First Principles

Bushick

Kioupakis

2023

Phys. Rev. Lett.

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Impact of phonons and spin-orbit coupling on Auger recombination in InAs

Cited by 3 publications

References 35 publications

Phonon-assisted Auger-Meitner Recombination in Silicon from First Principles

Phonon-assisted Auger-Meitner Recombination in Silicon from First Principles

Intrinsic carrier losses in tellurium due to radiative and Auger recombinations

Phonon-Assisted Auger-Meitner Recombination in Silicon from First Principles

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