Increasing the Rate of Magnesium Intercalation Underneath Epitaxial Graphene on 6H-SiC(0001)

Jimmy C. Kotsakidis; Marc Currie; Antonija Grubišić-Čabo; Anton Tadich; Rachael L. Myers-Ward; Matthew DeJarld; Kevin M. Daniels; Chang Liu; Mark T. Edmonds; Amadeo L. Vázquez de Parga; Michael S. Fuhrer; D. Kurt Gaskill

doi:10.1002/admi.202101598

Increasing the Rate of Magnesium Intercalation Underneath Epitaxial Graphene on 6H-SiC(0001)

Jimmy C. Kotsakidis, Marc Currie, Antonija Grubišić-Čabo, Anton Tadich, Rachael L. Myers-Ward, Matthew DeJarld, Kevin M. Daniels, Chang Liu, Mark T. Edmonds, Amadeo L. Vázquez de Parga, Michael S. Fuhrer, D. Kurt Gaskill

School of Physics and Astronomy

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

5 Citations (Scopus)

Abstract

Magnesium intercalated “quasi-freestanding” bilayer graphene on 6H-SiC(0001) (Mg-QFSBLG) has many favorable properties (e.g., highly n-type doped, relatively stable in ambient conditions). However, intercalation of Mg underneath monolayer graphene is challenging, requiring multiple intercalation steps. Here, these challenges are overcome and the rate of Mg intercalation is significantly increased by laser patterning (ablating) the graphene to form micron-sized discontinuities. Low energy electron diffraction is then used to verify Mg-intercalation and conversion to Mg-QFSBLG, and X-ray photoelectron spectroscopy to determine the Mg intercalation rate for patterned and non-patterned samples. By modeling Mg intercalation with the Verhulst equation, it is found that the intercalation rate increase for the patterned sample is 4.5 ± 1.7. Since the edge length of the patterned sample is ≈5.2 times that of the non-patterned sample, the model implies that the increased intercalation rate is proportional to the increase in edge length. Moreover, Mg intercalation likely begins at graphene discontinuities in pristine samples (not step edges or flat terraces), where the 2D-like crystal growth of Mg-silicide proceeds. The laser patterning technique may enable the rapid intercalation of other atomic or molecular species, thereby expanding upon the library of intercalants used to modify the characteristics of graphene, or other 2D materials and heterostructures.

Original language	English
Article number	2101598
Number of pages	11
Journal	Advanced Materials Interfaces
Volume	8
Issue number	23
DOIs	https://doi.org/10.1002/admi.202101598
Publication status	Published - 8 Dec 2021

Keywords

epitaxial graphene
graphene
intercalation
magnesium
silicon carbide

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10.1002/admi.202101598

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Kotsakidis, J. C., Currie, M., Grubišić-Čabo, A., Tadich, A., Myers-Ward, R. L., DeJarld, M., Daniels, K. M., Liu, C., Edmonds, M. T., Vázquez de Parga, A. L., Fuhrer, M. S., & Gaskill, D. K. (2021). Increasing the Rate of Magnesium Intercalation Underneath Epitaxial Graphene on 6H-SiC(0001). Advanced Materials Interfaces, 8(23), Article 2101598. https://doi.org/10.1002/admi.202101598

@article{ec0c0d8d042942c5af890fe05a728767,

title = "Increasing the Rate of Magnesium Intercalation Underneath Epitaxial Graphene on 6H-SiC(0001)",

abstract = "Magnesium intercalated “quasi-freestanding” bilayer graphene on 6H-SiC(0001) (Mg-QFSBLG) has many favorable properties (e.g., highly n-type doped, relatively stable in ambient conditions). However, intercalation of Mg underneath monolayer graphene is challenging, requiring multiple intercalation steps. Here, these challenges are overcome and the rate of Mg intercalation is significantly increased by laser patterning (ablating) the graphene to form micron-sized discontinuities. Low energy electron diffraction is then used to verify Mg-intercalation and conversion to Mg-QFSBLG, and X-ray photoelectron spectroscopy to determine the Mg intercalation rate for patterned and non-patterned samples. By modeling Mg intercalation with the Verhulst equation, it is found that the intercalation rate increase for the patterned sample is 4.5 ± 1.7. Since the edge length of the patterned sample is ≈5.2 times that of the non-patterned sample, the model implies that the increased intercalation rate is proportional to the increase in edge length. Moreover, Mg intercalation likely begins at graphene discontinuities in pristine samples (not step edges or flat terraces), where the 2D-like crystal growth of Mg-silicide proceeds. The laser patterning technique may enable the rapid intercalation of other atomic or molecular species, thereby expanding upon the library of intercalants used to modify the characteristics of graphene, or other 2D materials and heterostructures.",

keywords = "epitaxial graphene, graphene, intercalation, magnesium, silicon carbide",

author = "Kotsakidis, \{Jimmy C.\} and Marc Currie and Antonija Grubi{\v s}i{\'c}-{\v C}abo and Anton Tadich and Myers-Ward, \{Rachael L.\} and Matthew DeJarld and Daniels, \{Kevin M.\} and Chang Liu and Edmonds, \{Mark T.\} and \{V{\'a}zquez de Parga\}, \{Amadeo L.\} and Fuhrer, \{Michael S.\} and Gaskill, \{D. Kurt\}",

note = "Funding Information: J.C.K. acknowledges the hospitality of the U.S. Naval Research Laboratory (NRL) and for insightful discussions and use of equipment. J.C.K. acknowledges the Australian Government Research Training Program and the Monash Centre for Atomically Thin Materials (MCATM) for financial support. J.C.K. and M.S.F. acknowledge funding support for the Australian Research Council (ARC) Laureate Fellowship (FL120100038) and the ARC Centre of Excellence in Future Low‐Energy Electronics (CE170100039). A.L.V.P. acknowledges funding support from the Ministerio de Ciencia Innovati{\'o}n y Universidades project PGC2018‐093291‐B‐I00 and Comunidad de Madrid Project NMAT2D‐CM P2018/NMT‐4511. D.K.G., R.L.M.‐W., M.D., K.M.D., and M.C. acknowledge support by core programs at the U.S. Naval Research Laboratory funded by the Office of Naval Research. This research was undertaken on the soft X‐ray beamline at the Australian Synchrotron, part of ANSTO. Publisher Copyright: {\textcopyright} 2021 Wiley-VCH GmbH",

year = "2021",

month = dec,

day = "8",

doi = "10.1002/admi.202101598",

language = "English",

volume = "8",

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T1 - Increasing the Rate of Magnesium Intercalation Underneath Epitaxial Graphene on 6H-SiC(0001)

AU - Kotsakidis, Jimmy C.

AU - Currie, Marc

AU - Grubišić-Čabo, Antonija

AU - Tadich, Anton

AU - Myers-Ward, Rachael L.

AU - DeJarld, Matthew

AU - Daniels, Kevin M.

AU - Liu, Chang

AU - Edmonds, Mark T.

AU - Vázquez de Parga, Amadeo L.

AU - Fuhrer, Michael S.

AU - Gaskill, D. Kurt

N1 - Funding Information: J.C.K. acknowledges the hospitality of the U.S. Naval Research Laboratory (NRL) and for insightful discussions and use of equipment. J.C.K. acknowledges the Australian Government Research Training Program and the Monash Centre for Atomically Thin Materials (MCATM) for financial support. J.C.K. and M.S.F. acknowledge funding support for the Australian Research Council (ARC) Laureate Fellowship (FL120100038) and the ARC Centre of Excellence in Future Low‐Energy Electronics (CE170100039). A.L.V.P. acknowledges funding support from the Ministerio de Ciencia Innovatión y Universidades project PGC2018‐093291‐B‐I00 and Comunidad de Madrid Project NMAT2D‐CM P2018/NMT‐4511. D.K.G., R.L.M.‐W., M.D., K.M.D., and M.C. acknowledge support by core programs at the U.S. Naval Research Laboratory funded by the Office of Naval Research. This research was undertaken on the soft X‐ray beamline at the Australian Synchrotron, part of ANSTO. Publisher Copyright: © 2021 Wiley-VCH GmbH

PY - 2021/12/8

Y1 - 2021/12/8

N2 - Magnesium intercalated “quasi-freestanding” bilayer graphene on 6H-SiC(0001) (Mg-QFSBLG) has many favorable properties (e.g., highly n-type doped, relatively stable in ambient conditions). However, intercalation of Mg underneath monolayer graphene is challenging, requiring multiple intercalation steps. Here, these challenges are overcome and the rate of Mg intercalation is significantly increased by laser patterning (ablating) the graphene to form micron-sized discontinuities. Low energy electron diffraction is then used to verify Mg-intercalation and conversion to Mg-QFSBLG, and X-ray photoelectron spectroscopy to determine the Mg intercalation rate for patterned and non-patterned samples. By modeling Mg intercalation with the Verhulst equation, it is found that the intercalation rate increase for the patterned sample is 4.5 ± 1.7. Since the edge length of the patterned sample is ≈5.2 times that of the non-patterned sample, the model implies that the increased intercalation rate is proportional to the increase in edge length. Moreover, Mg intercalation likely begins at graphene discontinuities in pristine samples (not step edges or flat terraces), where the 2D-like crystal growth of Mg-silicide proceeds. The laser patterning technique may enable the rapid intercalation of other atomic or molecular species, thereby expanding upon the library of intercalants used to modify the characteristics of graphene, or other 2D materials and heterostructures.

AB - Magnesium intercalated “quasi-freestanding” bilayer graphene on 6H-SiC(0001) (Mg-QFSBLG) has many favorable properties (e.g., highly n-type doped, relatively stable in ambient conditions). However, intercalation of Mg underneath monolayer graphene is challenging, requiring multiple intercalation steps. Here, these challenges are overcome and the rate of Mg intercalation is significantly increased by laser patterning (ablating) the graphene to form micron-sized discontinuities. Low energy electron diffraction is then used to verify Mg-intercalation and conversion to Mg-QFSBLG, and X-ray photoelectron spectroscopy to determine the Mg intercalation rate for patterned and non-patterned samples. By modeling Mg intercalation with the Verhulst equation, it is found that the intercalation rate increase for the patterned sample is 4.5 ± 1.7. Since the edge length of the patterned sample is ≈5.2 times that of the non-patterned sample, the model implies that the increased intercalation rate is proportional to the increase in edge length. Moreover, Mg intercalation likely begins at graphene discontinuities in pristine samples (not step edges or flat terraces), where the 2D-like crystal growth of Mg-silicide proceeds. The laser patterning technique may enable the rapid intercalation of other atomic or molecular species, thereby expanding upon the library of intercalants used to modify the characteristics of graphene, or other 2D materials and heterostructures.

KW - epitaxial graphene

KW - graphene

KW - intercalation

KW - magnesium

KW - silicon carbide

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DO - 10.1002/admi.202101598

M3 - Article

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VL - 8

JO - Advanced Materials Interfaces

JF - Advanced Materials Interfaces

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M1 - 2101598

ER -

Increasing the Rate of Magnesium Intercalation Underneath Epitaxial Graphene on 6H-SiC(0001)

Abstract

Keywords

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ARC Centre of Excellence in Future Low-energy Electronics Technologies

Understanding and Controlling the Properties of Dirac Electronic Materials

Cite this

Increasing the Rate of Magnesium Intercalation Underneath Epitaxial Graphene on 6H-SiC(0001)

Abstract

Keywords

Access to Document

Other files and links

Projects

ARC Centre of Excellence in Future Low-energy Electronics Technologies

Understanding and Controlling the Properties of Dirac Electronic Materials

Cite this