Mapping nanoscale carrier confinement in polycrystalline graphene by terahertz spectroscopy

Patrick Rebsdorf Whelan; Domenico De Fazio; Iwona Pasternak; Joachim D. Thomsen; Steffen Zelzer; Martin O. Mikkelsen; Timothy J. Booth; Lars Diekhöner; Ugo Sassi; Duncan Johnstone; Paul A. Midgley; Wlodek Strupinski; Peter U. Jepsen; Andrea C. Ferrari; Peter Bøggild

doi:10.1038/s41598-024-51548-z

Mapping nanoscale carrier confinement in polycrystalline graphene by terahertz spectroscopy

Patrick Rebsdorf Whelan, Domenico De Fazio, Iwona Pasternak, Joachim D. Thomsen, Steffen Zelzer, Martin O. Mikkelsen, Timothy J. Booth, Lars Diekhöner, Ugo Sassi, Duncan Johnstone, Paul A. Midgley, Wlodek Strupinski, Peter U. Jepsen, Andrea C. Ferrari, Peter Bøggild

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

Abstract

Terahertz time-domain spectroscopy (THz-TDS) can be used to map spatial variations in electrical properties such as sheet conductivity, carrier density, and carrier mobility in graphene. Here, we consider wafer-scale graphene grown on germanium by chemical vapor deposition with non-uniformities and small domains due to reconstructions of the substrate during growth. The THz conductivity spectrum matches the predictions of the phenomenological Drude–Smith model for conductors with non-isotropic scattering caused by backscattering from boundaries and line defects. We compare the charge carrier mean free path determined by THz-TDS with the average defect distance assessed by Raman spectroscopy, and the grain boundary dimensions as determined by transmission electron microscopy. The results indicate that even small angle orientation variations below 5° within graphene grains influence the scattering behavior, consistent with significant backscattering contributions from grain boundaries.

Originalsprog	Engelsk
Artikelnummer	3163
Tidsskrift	Scientific Reports
Vol/bind	14
Udgave nummer	1
ISSN	2045-2322
DOI	https://doi.org/10.1038/s41598-024-51548-z
Status	Udgivet - 7 feb. 2024

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Whelan, P. R., De Fazio, D., Pasternak, I., Thomsen, J. D., Zelzer, S., Mikkelsen, M. O., Booth, T. J., Diekhöner, L., Sassi, U., Johnstone, D., Midgley, P. A., Strupinski, W., Jepsen, P. U., Ferrari, A. C., & Bøggild, P. (2024). Mapping nanoscale carrier confinement in polycrystalline graphene by terahertz spectroscopy. Scientific Reports, 14(1), Artikel 3163. https://doi.org/10.1038/s41598-024-51548-z

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title = "Mapping nanoscale carrier confinement in polycrystalline graphene by terahertz spectroscopy",

abstract = "Terahertz time-domain spectroscopy (THz-TDS) can be used to map spatial variations in electrical properties such as sheet conductivity, carrier density, and carrier mobility in graphene. Here, we consider wafer-scale graphene grown on germanium by chemical vapor deposition with non-uniformities and small domains due to reconstructions of the substrate during growth. The THz conductivity spectrum matches the predictions of the phenomenological Drude–Smith model for conductors with non-isotropic scattering caused by backscattering from boundaries and line defects. We compare the charge carrier mean free path determined by THz-TDS with the average defect distance assessed by Raman spectroscopy, and the grain boundary dimensions as determined by transmission electron microscopy. The results indicate that even small angle orientation variations below 5° within graphene grains influence the scattering behavior, consistent with significant backscattering contributions from grain boundaries.",

author = "Whelan, {Patrick Rebsdorf} and {De Fazio}, Domenico and Iwona Pasternak and Thomsen, {Joachim D.} and Steffen Zelzer and Mikkelsen, {Martin O.} and Booth, {Timothy J.} and Lars Diekh{\"o}ner and Ugo Sassi and Duncan Johnstone and Midgley, {Paul A.} and Wlodek Strupinski and Jepsen, {Peter U.} and Ferrari, {Andrea C.} and Peter B{\o}ggild",

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doi = "10.1038/s41598-024-51548-z",

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Whelan, PR, De Fazio, D, Pasternak, I, Thomsen, JD, Zelzer, S, Mikkelsen, MO, Booth, TJ, Diekhöner, L, Sassi, U, Johnstone, D, Midgley, PA, Strupinski, W, Jepsen, PU, Ferrari, AC & Bøggild, P 2024, 'Mapping nanoscale carrier confinement in polycrystalline graphene by terahertz spectroscopy', Scientific Reports, bind 14, nr. 1, 3163. https://doi.org/10.1038/s41598-024-51548-z

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T1 - Mapping nanoscale carrier confinement in polycrystalline graphene by terahertz spectroscopy

AU - Whelan, Patrick Rebsdorf

AU - De Fazio, Domenico

AU - Pasternak, Iwona

AU - Thomsen, Joachim D.

AU - Zelzer, Steffen

AU - Mikkelsen, Martin O.

AU - Booth, Timothy J.

AU - Diekhöner, Lars

AU - Sassi, Ugo

AU - Johnstone, Duncan

AU - Midgley, Paul A.

AU - Strupinski, Wlodek

AU - Jepsen, Peter U.

AU - Ferrari, Andrea C.

AU - Bøggild, Peter

PY - 2024/2/7

Y1 - 2024/2/7

N2 - Terahertz time-domain spectroscopy (THz-TDS) can be used to map spatial variations in electrical properties such as sheet conductivity, carrier density, and carrier mobility in graphene. Here, we consider wafer-scale graphene grown on germanium by chemical vapor deposition with non-uniformities and small domains due to reconstructions of the substrate during growth. The THz conductivity spectrum matches the predictions of the phenomenological Drude–Smith model for conductors with non-isotropic scattering caused by backscattering from boundaries and line defects. We compare the charge carrier mean free path determined by THz-TDS with the average defect distance assessed by Raman spectroscopy, and the grain boundary dimensions as determined by transmission electron microscopy. The results indicate that even small angle orientation variations below 5° within graphene grains influence the scattering behavior, consistent with significant backscattering contributions from grain boundaries.

AB - Terahertz time-domain spectroscopy (THz-TDS) can be used to map spatial variations in electrical properties such as sheet conductivity, carrier density, and carrier mobility in graphene. Here, we consider wafer-scale graphene grown on germanium by chemical vapor deposition with non-uniformities and small domains due to reconstructions of the substrate during growth. The THz conductivity spectrum matches the predictions of the phenomenological Drude–Smith model for conductors with non-isotropic scattering caused by backscattering from boundaries and line defects. We compare the charge carrier mean free path determined by THz-TDS with the average defect distance assessed by Raman spectroscopy, and the grain boundary dimensions as determined by transmission electron microscopy. The results indicate that even small angle orientation variations below 5° within graphene grains influence the scattering behavior, consistent with significant backscattering contributions from grain boundaries.

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Mapping nanoscale carrier confinement in polycrystalline graphene by terahertz spectroscopy

Abstract

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