The thermoelectric properties of Ge/SiGe modulation doped superlattices

Antonio Samarelli; Lourdes Ferre-LLin; Stefano Cecchi; J. Frigerio; Tanja Etzelstorfer; Elisabeth Müller-Gubler; Y. Zhang; J. R. Watling; Daniel Chrastina; G. Isella; Julian Stangl; J. P. Hague; J.M.R. Weaver; P. Dobson; Douglas J. Paul

doi:10.1063/1.4811228

The thermoelectric properties of Ge/SiGe modulation doped superlattices

Antonio Samarelli, Lourdes Ferre-LLin, Stefano Cecchi, J. Frigerio, Tanja Etzelstorfer, Elisabeth Müller-Gubler, Y. Zhang, J. R. Watling, Daniel Chrastina, G. Isella, Julian Stangl, J. P. Hague, J.M.R. Weaver, P. Dobson, Douglas J. Paul

Department of Semiconductor Physics

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

Abstract

The thermoelectric and physical properties of superlattices consisting of modulation doped Ge quantum wells inside Si1− y Ge y barriers are presented, which demonstrate enhancements in the thermoelectric figure of merit, ZT, and power factor at room temperature over bulk Ge, Si1− y Ge y , and Si/Ge superlattice materials. Mobility spectrum analysis along with low temperature measurements indicate that the high power factors are dominated by the high electrical conductivity from the modulation doping. Comparison of the results with modelling using the Boltzmann transport equation with scattering parameters obtained from Monte Carlo techniques indicates that a high threading dislocation density is also limiting the performance. The analysis suggests routes to higher thermoelectric performance at room temperature from Si-based materials that can be fabricated using micro- and nano-fabrication techniques.

Original language	English
Article number	233704
Pages (from-to)	233704
Number of pages	13
Journal	Journal of Applied Physics
Volume	113
Issue number	23
DOIs	https://doi.org/10.1063/1.4811228
Publication status	Published - 2013

Fields of science

103 Physics, Astronomy

JKU Focus areas

Nano-, Bio- and Polymer-Systems: From Structure to Function

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1063/1.4811228

Cite this

Samarelli, A., Ferre-LLin, L., Cecchi, S., Frigerio, J., Etzelstorfer, T., Müller-Gubler, E., Zhang, Y., Watling, J. R., Chrastina, D., Isella, G., Stangl, J., Hague, J. P., Weaver, J. M. R., Dobson, P., & Paul, D. J. (2013). The thermoelectric properties of Ge/SiGe modulation doped superlattices. Journal of Applied Physics, 113(23), 233704. Article 233704. https://doi.org/10.1063/1.4811228

@article{59da8eef90ad4d5daad9991f69816570,

title = "The thermoelectric properties of Ge/SiGe modulation doped superlattices",

abstract = "The thermoelectric and physical properties of superlattices consisting of modulation doped Ge quantum wells inside Si1− y Ge y barriers are presented, which demonstrate enhancements in the thermoelectric figure of merit, ZT, and power factor at room temperature over bulk Ge, Si1− y Ge y , and Si/Ge superlattice materials. Mobility spectrum analysis along with low temperature measurements indicate that the high power factors are dominated by the high electrical conductivity from the modulation doping. Comparison of the results with modelling using the Boltzmann transport equation with scattering parameters obtained from Monte Carlo techniques indicates that a high threading dislocation density is also limiting the performance. The analysis suggests routes to higher thermoelectric performance at room temperature from Si-based materials that can be fabricated using micro- and nano-fabrication techniques.",

author = "Antonio Samarelli and Lourdes Ferre-LLin and Stefano Cecchi and J. Frigerio and Tanja Etzelstorfer and Elisabeth M{\"u}ller-Gubler and Y. Zhang and Watling, \{J. R.\} and Daniel Chrastina and G. Isella and Julian Stangl and Hague, \{J. P.\} and J.M.R. Weaver and P. Dobson and Paul, \{Douglas J.\}",

year = "2013",

doi = "10.1063/1.4811228",

language = "English",

volume = "113",

pages = "233704",

journal = "Journal of Applied Physics",

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publisher = "American Institute of Physics",

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Samarelli, A, Ferre-LLin, L, Cecchi, S, Frigerio, J, Etzelstorfer, T, Müller-Gubler, E, Zhang, Y, Watling, JR, Chrastina, D, Isella, G, Stangl, J, Hague, JP, Weaver, JMR, Dobson, P & Paul, DJ 2013, 'The thermoelectric properties of Ge/SiGe modulation doped superlattices', Journal of Applied Physics, vol. 113, no. 23, 233704, pp. 233704. https://doi.org/10.1063/1.4811228

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T1 - The thermoelectric properties of Ge/SiGe modulation doped superlattices

AU - Samarelli, Antonio

AU - Ferre-LLin, Lourdes

AU - Cecchi, Stefano

AU - Frigerio, J.

AU - Etzelstorfer, Tanja

AU - Müller-Gubler, Elisabeth

AU - Zhang, Y.

AU - Watling, J. R.

AU - Chrastina, Daniel

AU - Isella, G.

AU - Stangl, Julian

AU - Hague, J. P.

AU - Weaver, J.M.R.

AU - Dobson, P.

AU - Paul, Douglas J.

PY - 2013

Y1 - 2013

N2 - The thermoelectric and physical properties of superlattices consisting of modulation doped Ge quantum wells inside Si1− y Ge y barriers are presented, which demonstrate enhancements in the thermoelectric figure of merit, ZT, and power factor at room temperature over bulk Ge, Si1− y Ge y , and Si/Ge superlattice materials. Mobility spectrum analysis along with low temperature measurements indicate that the high power factors are dominated by the high electrical conductivity from the modulation doping. Comparison of the results with modelling using the Boltzmann transport equation with scattering parameters obtained from Monte Carlo techniques indicates that a high threading dislocation density is also limiting the performance. The analysis suggests routes to higher thermoelectric performance at room temperature from Si-based materials that can be fabricated using micro- and nano-fabrication techniques.

AB - The thermoelectric and physical properties of superlattices consisting of modulation doped Ge quantum wells inside Si1− y Ge y barriers are presented, which demonstrate enhancements in the thermoelectric figure of merit, ZT, and power factor at room temperature over bulk Ge, Si1− y Ge y , and Si/Ge superlattice materials. Mobility spectrum analysis along with low temperature measurements indicate that the high power factors are dominated by the high electrical conductivity from the modulation doping. Comparison of the results with modelling using the Boltzmann transport equation with scattering parameters obtained from Monte Carlo techniques indicates that a high threading dislocation density is also limiting the performance. The analysis suggests routes to higher thermoelectric performance at room temperature from Si-based materials that can be fabricated using micro- and nano-fabrication techniques.

U2 - 10.1063/1.4811228

DO - 10.1063/1.4811228

M3 - Article

SN - 1089-7550

VL - 113

SP - 233704

JO - Journal of Applied Physics

JF - Journal of Applied Physics

IS - 23

M1 - 233704

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