Au-rich filamentary behavior and associated subband gap optical absorption in hyperdoped Si

Date

2017

Authors

Yang, Wenjie
Akey, Austin J.
Smillie, Lachlan
Mailoa, Jonathan P.
Johnson, B. C.
McCallum, J. C.
Macdonald, Daniel
Buonassisi, Tonio
Aziz, Michael
Williams, James

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Volume Title

Publisher

American Physical Society

Abstract

Au-hyperdoped Si, synthesized by ion implantation and pulsed laser melting, is known to exhibit a strong sub-band gap photoresponse that scales monotonically with the Au concentration. However, there is thought to be a limit to this behavior since ultrahigh Au concentrations (>1 x 10(20) cm(-3)) are expected to induce cellular breakdown during the rapid resolidification of Si, a process that is associated with significant lateral impurity precipitation. This work shows that the cellular morphology observed in Au-hyperdoped Si differs from that in conventional, steady-state cellular breakdown. In particular, Rutherford backscattering spectrometry combined with channeling and transmission electron microscopy revealed an inhomogeneous Au distribution and a subsurface network of Au-rich filaments, within which the Au impurities largely reside on substitutional positions in the crystalline Si lattice, at concentrations as high as similar to 3 at. %. The measured substitutional Au dose, regardless of the presence of Au-rich filaments, correlates strongly with the sub-band gap optical absorptance. Upon subsequent thermal treatment, the supersaturated Au forms precipitates, while the Au substitutionality and the sub-band gap optical absorption both decrease. These results offer insight into a metastable filamentary regime in Au-hyperdoped Si that has important implications for Si-based infrared optoelectronics.

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Source

Physical Review Materials

Type

Journal article

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Access Statement

Open Access

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