Ultra-doped n-type germanium thin films for sensing in the mid-infrared

Prucnal, S.; Liu, Fang; Voelskow, M.; Vines, Lasse; Rebohle, L.; Lang, Denny; Berencén, Yonder; Andric, Stefan; Boettger, R.; Helm, M.; Zhou, Shengqiang; Skorupa, W.

doi:10.1038/srep27643

Cited by 69 publications

(67 citation statements)

References 44 publications

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“…During recent years, flash lamp annealing (FLA) has been used as an annealing method in the ms-range for many purposes, especially driven by the needs of advanced semiconductor processing, see Refs. 14-16 for recent reviews, and more specific, also those of Ge-based materials research: shallow junctions [17], nanoclusters [18], advanced processing [10,19] etc.…”

Section: Methodsmentioning

confidence: 99%

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Strain and Band-Gap Engineering in Ge - Sn Alloys via P Doping

et al. 2018

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Ge with a quasi-direct band gap can be realized by strain engineering, alloying with Sn or ultra-high n-type doping. In this paper, we use all three approaches together -strain engineering, Sn alloying and n-type doping to fabricate direct band gap GeSn alloys. The heavily-doped n-type GeSn was realized using a CMOS-compatible non-equilibrium material processing. P is used to form a highly-doped n-type GeSn layers and to modify the lattice parameter of GeSn:P alloys. The strain engineering in heavily P-doped GeSn films is confirmed by X-ray diffraction and micro-Raman spectroscopy. The change of the band gap in GeSn:P alloy as a function of P concentration is theoretically predicted using density functional theory and experimentally verified by near-infrared spectroscopic ellipsometry.According to the shift of the absorption edge it is shown that for an electron concentration above 1×10 20 cm -3 the band gap renormalization is partially compensated by the Burstein-Moss effect. These results indicate that Ge-based materials have a large potential for the nearinfrared optoelectronic devices, fully compatible with CMOS technology.

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Section: Methodsmentioning

confidence: 99%

“…The ultra-doped n-type GeSn layer-on-Si is fabricated by ion implantation of Sn and P into Ge-on-Si wafers followed by non-equilibrium ms-range rear-side flash-lamp annealing (r-FLA). Recrystallization of the implanted layer and the electrical activation of P induce explosive solid-phase epitaxy (ESPE) regrowth [10,11].…”

Section: Introductionmentioning

confidence: 99%

Strain and Band-Gap Engineering in Ge - Sn Alloys via P Doping

et al. 2018

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“…For a short moment (in the sub-microsecond range), the surface is much hotter than the amorphous/crystalline interface. Also, the threshold energy needed for crystalline seed nucleation is lower than the energy needed for the epitaxial regrowth [32]. Therefore, during f-FLA, the recrystallization of the implanted layer starts from the surface and a polycrystalline layer is formed.…”

Section: Sample Fabricationmentioning

confidence: 99%

“…Since the discovery of superconductivity in diamond [1] with a boron content above the equilibrium solid solubility (ESS) many studies have been performed to find new "superconducting semiconductors". Such a materials class would enable the monolithic integration of quantum and conventional electronics [2]. Indeed, several groups found superconductivity, even in the technologically more relevant semiconductors like Si [3], Ge [4] or SiC [5], after a heavy hole doping.…”

Section: Introductionmentioning

confidence: 99%

Superconductivity in single-crystalline aluminum- and gallium-hyperdoped germanium

Prucnal

Heera

Hübner

et al. 2019

Phys. Rev. Materials

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Superconductivity in group IV semiconductors is desired for hybrid devices combining both semiconducting and superconducting properties. Following boron doped diamond and Si, superconductivity has been observed in gallium doped Ge, however the obtained specimen is in polycrystalline form [Herrmannsdörfer et al., Phys. Rev. Lett. 102, 217003 (2009)]. Here, we present superconducting single-crystalline Ge hyperdoped with gallium or aluminium by ion implantation and rear-side flash lamp annealing. The maximum concentration of Al and Ga incorporated into substitutional positions in Ge is eight times higher than the equilibrium solid solubility. This corresponds to a hole concentration above 10 21 cm -3 . Using density functional theory in the local density approximation and pseudopotential plane-wave approach, we show that the superconductivity in p-type Ge is phonon-mediated. According to the ab initio calculations the critical superconducting temperature for Al-and Ga-doped Ge is in the range of 0.45 K for 6.25 at.% of dopant concentration being in a qualitative agreement with experimentally obtained values.

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“…Nanoantennas have indeed been realized in the n-Ge material system epitaxially grown on the Si wafers; 20 however in that case, doping levels of about 0.2 Â 10 20 cm À3 , obtained by co-deposition of the dopant P and Ge, have still limited the nanoantenna operation at k > 11 lm with k p ¼ 9.3 lm. Very recently, 21 a shorter k p ¼ 5.5 lm was reported for the ion-implanted n-Ge thin films, but no antenna structures were fabricated in that case.…”

Section: à3mentioning

confidence: 99%

Mapping the electromagnetic field confinement in the gap of germanium nanoantennas with plasma wavelength of 4.5 micrometers

Calandrini

Venanzi

Appugliese

et al. 2016

Applied Physics Letters

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We study plasmonic nanoantennas for molecular sensing in the mid-infrared made of heavily doped germanium, epitaxially grown with a bottom-up doping process and featuring free carrier density in excess of 1020 cm−3. The dielectric function of the 250 nm thick germanium film is determined, and bow-tie antennas are designed, fabricated, and embedded in a polymer. By using a near-field photoexpansion mapping technique at λ = 5.8 μm, we demonstrate the existence in the antenna gap of an electromagnetic energy density hotspot of diameter below 100 nm and confinement volume 105 times smaller than λ3

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Ultra-doped n-type germanium thin films for sensing in the mid-infrared

Cited by 69 publications

References 44 publications

Strain and Band-Gap Engineering in Ge - Sn Alloys via P Doping

Strain and Band-Gap Engineering in Ge - Sn Alloys via P Doping

Superconductivity in single-crystalline aluminum- and gallium-hyperdoped germanium

Mapping the electromagnetic field confinement in the gap of germanium nanoantennas with plasma wavelength of 4.5 micrometers

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