Deactivation of metastable single-crystal silicon hyperdoped with sulfur

Simmons, C. B.; Akey, Austin; Krich, Jacob J.; Sullivan, Joseph T.; Recht, Daniel; Aziz, Michael J.; Buonassisi, Tonio

doi:10.1063/1.4854835

Cited by 47 publications

(44 citation statements)

References 42 publications

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“…The deactivation of sub-bandgap optical absorptance, which is associated with an increase in electron mobility and changes in sheet carrier concentration, has been explained using the Johnson-Mehl-AvramiKolmogorov framework describing diffusion-mediated changes in metastable supersaturated solid solutions such as hyperdoped silicon. 31 However, the reactivation of the sub-bandgap optical absorptance after heating and fast cooling suggests that the degree of departure from room-temperature equilibrium of the dopant atoms, as reflected by the placement of the dopant atoms within the lattice, is reversible and important in describing the properties of hyperdoped silicon, similarly to the way in which fictive temperature is important in describing the properties of glasses -another non-equilibrium material. Reactivation has been previously reported when deactivated hyperdoped silicon was irradiated with fs laser pulses or heated to temperatures above 1350 K followed by fast cooling (e.g., in silicone oil, yielding estimated cooling rates of about 250 K/s).…”

Section: Discussionmentioning

confidence: 99%

Simultaneous high crystallinity and sub-bandgap optical absorptance in hyperdoped black silicon using nanosecond laser annealing

Franta

Pastor

Gandhi

et al. 2015

Journal of Applied Physics

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Hyperdoped black silicon fabricated with femtosecond laser irradiation has attracted interest for applications in infrared photodetectors and intermediate band photovoltaics due to its sub-bandgap optical absorptance and light-trapping surface. However, hyperdoped black silicon typically has an amorphous and polyphasic polycrystalline surface that can interfere with carrier transport, electrical rectification, and intermediate band formation. Past studies have used thermal annealing to obtain high crystallinity in hyperdoped black silicon, but thermal annealing causes a deactivation of the sub-bandgap optical absorptance. In this study, nanosecond laser annealing is used to obtain high crystallinity and remove pressure-induced phases in hyperdoped black silicon while maintaining high sub-bandgap optical absorptance and a light-trapping surface morphology. Furthermore, it is shown that nanosecond laser annealing reactivates the sub-bandgap optical absorptance of hyperdoped black silicon after deactivation by thermal annealing. Thermal annealing and nanosecond laser annealing can be combined in sequence to fabricate hyperdoped black silicon that simultaneously shows high crystallinity, high above-bandgap and sub-bandgap absorptance, and a rectifying electrical homojunction. Such nanosecond laser annealing could potentially be applied to non-equilibrium material systems beyond hyperdoped black silicon.

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Section: Discussionmentioning

confidence: 99%

Simultaneous high crystallinity and sub-bandgap optical absorptance in hyperdoped black silicon using nanosecond laser annealing

Franta

Pastor

Gandhi

et al. 2015

Journal of Applied Physics

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“…Some groups have thoroughly investigated Si supersaturated with S or Se prepared by laser irradiation in SF 6 atmosphere or by ion implantation and subsequently pulsed laser melted (PLM). [8][9][10][11][12] An extended infrared photoresponse with high gain levels has been shown. 13,14 In previous works, we have deeply investigated Si supersaturated with Ti 15 or V, 16 and we reported the first solar cell device based on Ti supersaturated Si.…”

Section: 2mentioning

confidence: 99%

Room-temperature operation of a titanium supersaturated silicon-based infrared photodetector

García-Hemme

García-Hernansanz

Olea³

et al. 2014

Applied Physics Letters

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We report room-temperature operation of 1 × 1 cm2 infrared photoconductive photodetectors based on silicon supersaturated with titanium. We have fabricated these Si-based infrared photodetectors devices by means of ion implantation followed by a pulsed laser melting process. A high sub-band gap responsivity of 34 mV W−1 has been obtained operating at the useful telecommunication applications wavelength of 1.55 μm (0.8 eV). The sub-band gap responsivity shows a cut-off frequency as high as 1.9 kHz. These Si-based devices exhibit a non-previous reported specific detectivity of 1.7 × 104 cm Hz1/2 W−1 at 660 Hz, under a 1.55 μm wavelength light. This work shows the potential of Ti supersaturated Si as a fully CMOS-compatible material for the infrared photodetection technology.

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“…Both pulsed laser annealing in the nanosecond range [8,14] and furnace annealing in the minute one [15,16] have been used to activate S and Se dopants in Si introduced by ion implantation. However, the long-time process required for furnace annealing or even few seconds for rapid thermal annealing will cause large possibilities for impurity diffusion, resulting in a low substitutional fraction [15] or a deactivation of dopants [17]. During pulsed laser annealing the surface temperature exceeds the melting point, subsequently leading to liquid-phase epitaxial regrowth.…”

Section: Introductionmentioning

confidence: 99%

Realizing the insulator-to-metal transition in Se-hyperdoped Si via non-equilibrium material processing

Liu¹,

Prucnal²,

Berencén³

et al. 2017

J. Phys. D: Appl. Phys.

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Deactivation of metastable single-crystal silicon hyperdoped with sulfur

Cited by 47 publications

References 42 publications

Simultaneous high crystallinity and sub-bandgap optical absorptance in hyperdoped black silicon using nanosecond laser annealing

Simultaneous high crystallinity and sub-bandgap optical absorptance in hyperdoped black silicon using nanosecond laser annealing

Room-temperature operation of a titanium supersaturated silicon-based infrared photodetector

Realizing the insulator-to-metal transition in Se-hyperdoped Si via non-equilibrium material processing

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