A room-temperature-operated Si LED with β-FeSi2 nanocrystals in the active layer

Standard

A room-temperature-operated Si LED with β-FeSi₂ nanocrystals in the active layer : μW emission power at 1.5 μm. / Shevlyagin, A. V.; Goroshko, D. L.; Chusovitin, E. A. et al.

In: Journal of Applied Physics, Vol. 121, No. 11, 113101, 21.03.2017.

Research output: Contribution to journal › Article › peer-review

Harvard

Shevlyagin, AV, Goroshko, DL, Chusovitin, EA, Balagan, SA, Dotcenko, SA, Galkin, KN, Galkin, NG, Shamirzaev, TS, Gutakovskii, AK, Latyshev, AV, Iinuma, M & Terai, Y 2017, 'A room-temperature-operated Si LED with β-FeSi₂ nanocrystals in the active layer: μW emission power at 1.5 μm', Journal of Applied Physics, vol. 121, no. 11, 113101. https://doi.org/10.1063/1.4978372

APA

Shevlyagin, A. V., Goroshko, D. L., Chusovitin, E. A., Balagan, S. A., Dotcenko, S. A., Galkin, K. N., Galkin, N. G., Shamirzaev, T. S., Gutakovskii, A. K., Latyshev, A. V., Iinuma, M., & Terai, Y. (2017). A room-temperature-operated Si LED with β-FeSi₂ nanocrystals in the active layer: μW emission power at 1.5 μm. Journal of Applied Physics, 121(11), [113101]. https://doi.org/10.1063/1.4978372

Vancouver

Shevlyagin AV, Goroshko DL, Chusovitin EA, Balagan SA, Dotcenko SA, Galkin KN et al. A room-temperature-operated Si LED with β-FeSi₂ nanocrystals in the active layer: μW emission power at 1.5 μm. Journal of Applied Physics. 2017 Mar 21;121(11):113101. doi: 10.1063/1.4978372

Author

Shevlyagin, A. V. ; Goroshko, D. L. ; Chusovitin, E. A. et al. / A room-temperature-operated Si LED with β-FeSi₂ nanocrystals in the active layer : μW emission power at 1.5 μm. In: Journal of Applied Physics. 2017 ; Vol. 121, No. 11.

BibTeX

@article{a9da68df42af4ad0ba7ef8e0e850527e,

title = "A room-temperature-operated Si LED with β-FeSi2 nanocrystals in the active layer: μW emission power at 1.5 μm",

abstract = "This article describes the development of an Si-based light-emitting diode with β-FeSi2 nanocrystals embedded in the active layer. Favorable epitaxial conditions allow us to obtain a direct band gap type-I band alignment Si/β-FeSi2 nanocrystals/Si heterostructure with optical transition at a wavelength range of 1500-1550 nm at room temperature. Transmission electron microscopy data reveal strained, defect-free β-FeSi2 nanocrystals of diameter 6 and 25 nm embedded in the Si matrix. Intense electroluminescence was observed at a pumping current density as low as 0.7 A/cm2. The device reached an optical emission power of up to 25 μW at 9 A/cm2 with an external quantum efficiency of 0.009%. Watt-Ampere characteristic linearity suggests that the optical power margin of the light-emitting diode has not been exhausted. Band structure calculations explain the luminescence as being mainly due to radiative recombination in the large β-FeSi2 nanocrystals resulting from the realization of an indirect-to-direct band gap electronic configuration transformation arising from a favorable deformation of nanocrystals. The direct band gap structure and the measured short decay time of the luminescence of several tens of ns give rise to a fast operation speed for the device. Thus a method for developing a silicon-based photonic integrated circuit, combining complementary metal-oxide-semiconductor technology functionality and near-infrared light emission, is reported here.",

keywords = "MOLECULAR-BEAM EPITAXY, LIGHT-EMITTING DIODE, SEMICONDUCTING IRON DISILICIDE, TOTAL-ENERGY CALCULATIONS, WAVE BASIS-SET, THIN-FILMS, DOUBLE-HETEROSTRUCTURES, BETA-FESI2, SILICON, PHOTOLUMINESCENCE",

author = "Shevlyagin, {A. V.} and Goroshko, {D. L.} and Chusovitin, {E. A.} and Balagan, {S. A.} and Dotcenko, {S. A.} and Galkin, {K. N.} and Galkin, {N. G.} and Shamirzaev, {T. S.} and Gutakovskii, {A. K.} and Latyshev, {A. V.} and M. Iinuma and Y. Terai",

year = "2017",

month = mar,

day = "21",

doi = "10.1063/1.4978372",

language = "English",

volume = "121",

journal = "Journal of Applied Physics",

issn = "0021-8979",

publisher = "AMER INST PHYSICS",

number = "11",

}

RIS

TY - JOUR

T1 - A room-temperature-operated Si LED with β-FeSi2 nanocrystals in the active layer

T2 - μW emission power at 1.5 μm

AU - Shevlyagin, A. V.

AU - Goroshko, D. L.

AU - Chusovitin, E. A.

AU - Balagan, S. A.

AU - Dotcenko, S. A.

AU - Galkin, K. N.

AU - Galkin, N. G.

AU - Shamirzaev, T. S.

AU - Gutakovskii, A. K.

AU - Latyshev, A. V.

AU - Iinuma, M.

AU - Terai, Y.

PY - 2017/3/21

Y1 - 2017/3/21

N2 - This article describes the development of an Si-based light-emitting diode with β-FeSi2 nanocrystals embedded in the active layer. Favorable epitaxial conditions allow us to obtain a direct band gap type-I band alignment Si/β-FeSi2 nanocrystals/Si heterostructure with optical transition at a wavelength range of 1500-1550 nm at room temperature. Transmission electron microscopy data reveal strained, defect-free β-FeSi2 nanocrystals of diameter 6 and 25 nm embedded in the Si matrix. Intense electroluminescence was observed at a pumping current density as low as 0.7 A/cm2. The device reached an optical emission power of up to 25 μW at 9 A/cm2 with an external quantum efficiency of 0.009%. Watt-Ampere characteristic linearity suggests that the optical power margin of the light-emitting diode has not been exhausted. Band structure calculations explain the luminescence as being mainly due to radiative recombination in the large β-FeSi2 nanocrystals resulting from the realization of an indirect-to-direct band gap electronic configuration transformation arising from a favorable deformation of nanocrystals. The direct band gap structure and the measured short decay time of the luminescence of several tens of ns give rise to a fast operation speed for the device. Thus a method for developing a silicon-based photonic integrated circuit, combining complementary metal-oxide-semiconductor technology functionality and near-infrared light emission, is reported here.

AB - This article describes the development of an Si-based light-emitting diode with β-FeSi2 nanocrystals embedded in the active layer. Favorable epitaxial conditions allow us to obtain a direct band gap type-I band alignment Si/β-FeSi2 nanocrystals/Si heterostructure with optical transition at a wavelength range of 1500-1550 nm at room temperature. Transmission electron microscopy data reveal strained, defect-free β-FeSi2 nanocrystals of diameter 6 and 25 nm embedded in the Si matrix. Intense electroluminescence was observed at a pumping current density as low as 0.7 A/cm2. The device reached an optical emission power of up to 25 μW at 9 A/cm2 with an external quantum efficiency of 0.009%. Watt-Ampere characteristic linearity suggests that the optical power margin of the light-emitting diode has not been exhausted. Band structure calculations explain the luminescence as being mainly due to radiative recombination in the large β-FeSi2 nanocrystals resulting from the realization of an indirect-to-direct band gap electronic configuration transformation arising from a favorable deformation of nanocrystals. The direct band gap structure and the measured short decay time of the luminescence of several tens of ns give rise to a fast operation speed for the device. Thus a method for developing a silicon-based photonic integrated circuit, combining complementary metal-oxide-semiconductor technology functionality and near-infrared light emission, is reported here.

KW - MOLECULAR-BEAM EPITAXY

KW - LIGHT-EMITTING DIODE

KW - SEMICONDUCTING IRON DISILICIDE

KW - TOTAL-ENERGY CALCULATIONS

KW - WAVE BASIS-SET

KW - THIN-FILMS

KW - DOUBLE-HETEROSTRUCTURES

KW - BETA-FESI2

KW - SILICON

KW - PHOTOLUMINESCENCE

UR - http://www.scopus.com/inward/record.url?scp=85015433382&partnerID=8YFLogxK

U2 - 10.1063/1.4978372

DO - 10.1063/1.4978372

M3 - Article

AN - SCOPUS:85015433382

VL - 121

JO - Journal of Applied Physics

JF - Journal of Applied Physics

SN - 0021-8979

IS - 11

M1 - 113101

ER -

ID: 10273083