Domain Boundary Formation Within an Intercalated Pb Monolayer Featuring Charge-Neutral Epitaxial Graphene

Philip Schädlich; Chitran Ghosal; Monja Stettner; Bharti Matta; Susanne Wolff; Franziska Schölzel; Peter Richter; Mark Hutter; Anja Haags; Sabine Wenzel; Zamin Mamiyev; Julian Koch; Serguei Soubatch; Philipp Rosenzweig; Craig Polley; Frank Stefan Tautz; Christian Kumpf; Kathrin Küster; Ulrich Starke; Thomas Seyller; Francois C. Bocquet; Christoph Tegenkamp

doi:10.1002/admi.202300471

Domain Boundary Formation Within an Intercalated Pb Monolayer Featuring Charge-Neutral Epitaxial Graphene

Philip Schädlich, Chitran Ghosal, Monja Stettner, Bharti Matta, Susanne Wolff, Franziska Schölzel, Peter Richter, Mark Hutter, Anja Haags, Sabine Wenzel, Zamin Mamiyev, Julian Koch, Serguei Soubatch, Philipp Rosenzweig, Craig Polley, Frank Stefan Tautz, Christian Kumpf, Kathrin Küster, Ulrich Starke, Thomas SeyllerFrancois C. Bocquet, Christoph Tegenkamp

MAX IV-laboratoriet

Forskningsoutput: Tidskriftsbidrag › Artikel i vetenskaplig tidskrift › Peer review

Sammanfattning

The synthesis of new graphene-based quantum materials by intercalation is an auspicious approach. However, an accompanying proximity coupling depends crucially on the structural details of the new heterostructure. It is studied in detail the Pb monolayer structure after intercalation into the graphene buffer layer on the SiC(0001) interface by means of photoelectron spectroscopy, x-ray standing waves, and scanning tunneling microscopy. A coherent fraction close to unity proves the formation of a flat Pb monolayer on the SiC surface. An interlayer distance of 3.67 Å to the suspended graphene underlines the formation of a truly van der Waals heterostructure. The 2D Pb layer reveals a quasi ten-fold periodicity due to the formation of a grain boundary network, ensuring the saturation of the Si surface bonds. Moreover, the densely-packed Pb layer also efficiently minimizes the doping influence by the SiC substrate, both from the surface dangling bonds and the SiC surface polarization, giving rise to charge-neutral monolayer graphene. The observation of a long-ranged ((Formula presented.)) reconstruction on the graphene lattice at tunneling conditions close to Fermi energy is most likely a result of a nesting condition to be perfectly fulfilled.

Originalspråk	engelska
Tidskrift	Advanced Materials Interfaces
Volym	10
Nummer	27
Tidigt onlinedatum	2023
DOI	https://doi.org/10.1002/admi.202300471
Status	Published - 2023

Ämnesklassifikation (UKÄ)

Den kondenserade materiens fysik (Här ingår: Materialfysik, nanofysik)

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10.1002/admi.202300471

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Schädlich, P., Ghosal, C., Stettner, M., Matta, B., Wolff, S., Schölzel, F., Richter, P., Hutter, M., Haags, A., Wenzel, S., Mamiyev, Z., Koch, J., Soubatch, S., Rosenzweig, P., Polley, C., Tautz, F. S., Kumpf, C., Küster, K., Starke, U., ... Tegenkamp, C. (2023). Domain Boundary Formation Within an Intercalated Pb Monolayer Featuring Charge-Neutral Epitaxial Graphene. Advanced Materials Interfaces, 10(27). https://doi.org/10.1002/admi.202300471

@article{8469bb5dfd1e4eef92fe8431eed51f26,

title = "Domain Boundary Formation Within an Intercalated Pb Monolayer Featuring Charge-Neutral Epitaxial Graphene",

abstract = "The synthesis of new graphene-based quantum materials by intercalation is an auspicious approach. However, an accompanying proximity coupling depends crucially on the structural details of the new heterostructure. It is studied in detail the Pb monolayer structure after intercalation into the graphene buffer layer on the SiC(0001) interface by means of photoelectron spectroscopy, x-ray standing waves, and scanning tunneling microscopy. A coherent fraction close to unity proves the formation of a flat Pb monolayer on the SiC surface. An interlayer distance of 3.67 {\AA} to the suspended graphene underlines the formation of a truly van der Waals heterostructure. The 2D Pb layer reveals a quasi ten-fold periodicity due to the formation of a grain boundary network, ensuring the saturation of the Si surface bonds. Moreover, the densely-packed Pb layer also efficiently minimizes the doping influence by the SiC substrate, both from the surface dangling bonds and the SiC surface polarization, giving rise to charge-neutral monolayer graphene. The observation of a long-ranged ((Formula presented.)) reconstruction on the graphene lattice at tunneling conditions close to Fermi energy is most likely a result of a nesting condition to be perfectly fulfilled.",

keywords = "angle-resolved photoelectron sprectroscopy, charge-neutral epitaxial graphene, low energy electron diffraction, normal incidence x-ray standing wave, Pb monolayer intercalation, scanning tunneling microscopy, X-ray photoelectron spectroscopy",

author = "Philip Sch{\"a}dlich and Chitran Ghosal and Monja Stettner and Bharti Matta and Susanne Wolff and Franziska Sch{\"o}lzel and Peter Richter and Mark Hutter and Anja Haags and Sabine Wenzel and Zamin Mamiyev and Julian Koch and Serguei Soubatch and Philipp Rosenzweig and Craig Polley and Tautz, {Frank Stefan} and Christian Kumpf and Kathrin K{\"u}ster and Ulrich Starke and Thomas Seyller and Bocquet, {Francois C.} and Christoph Tegenkamp",

year = "2023",

doi = "10.1002/admi.202300471",

language = "English",

volume = "10",

journal = "Advanced Materials Interfaces",

issn = "2196-7350",

publisher = "John Wiley & Sons Inc.",

number = "27",

}

Schädlich, P, Ghosal, C, Stettner, M, Matta, B, Wolff, S, Schölzel, F, Richter, P, Hutter, M, Haags, A, Wenzel, S, Mamiyev, Z, Koch, J, Soubatch, S, Rosenzweig, P, Polley, C, Tautz, FS, Kumpf, C, Küster, K, Starke, U, Seyller, T, Bocquet, FC & Tegenkamp, C 2023, 'Domain Boundary Formation Within an Intercalated Pb Monolayer Featuring Charge-Neutral Epitaxial Graphene', Advanced Materials Interfaces, vol. 10, nr. 27. https://doi.org/10.1002/admi.202300471

TY - JOUR

T1 - Domain Boundary Formation Within an Intercalated Pb Monolayer Featuring Charge-Neutral Epitaxial Graphene

AU - Schädlich, Philip

AU - Ghosal, Chitran

AU - Stettner, Monja

AU - Matta, Bharti

AU - Wolff, Susanne

AU - Schölzel, Franziska

AU - Richter, Peter

AU - Hutter, Mark

AU - Haags, Anja

AU - Wenzel, Sabine

AU - Mamiyev, Zamin

AU - Koch, Julian

AU - Soubatch, Serguei

AU - Rosenzweig, Philipp

AU - Polley, Craig

AU - Tautz, Frank Stefan

AU - Kumpf, Christian

AU - Küster, Kathrin

AU - Starke, Ulrich

AU - Seyller, Thomas

AU - Bocquet, Francois C.

AU - Tegenkamp, Christoph

PY - 2023

Y1 - 2023

N2 - The synthesis of new graphene-based quantum materials by intercalation is an auspicious approach. However, an accompanying proximity coupling depends crucially on the structural details of the new heterostructure. It is studied in detail the Pb monolayer structure after intercalation into the graphene buffer layer on the SiC(0001) interface by means of photoelectron spectroscopy, x-ray standing waves, and scanning tunneling microscopy. A coherent fraction close to unity proves the formation of a flat Pb monolayer on the SiC surface. An interlayer distance of 3.67 Å to the suspended graphene underlines the formation of a truly van der Waals heterostructure. The 2D Pb layer reveals a quasi ten-fold periodicity due to the formation of a grain boundary network, ensuring the saturation of the Si surface bonds. Moreover, the densely-packed Pb layer also efficiently minimizes the doping influence by the SiC substrate, both from the surface dangling bonds and the SiC surface polarization, giving rise to charge-neutral monolayer graphene. The observation of a long-ranged ((Formula presented.)) reconstruction on the graphene lattice at tunneling conditions close to Fermi energy is most likely a result of a nesting condition to be perfectly fulfilled.

AB - The synthesis of new graphene-based quantum materials by intercalation is an auspicious approach. However, an accompanying proximity coupling depends crucially on the structural details of the new heterostructure. It is studied in detail the Pb monolayer structure after intercalation into the graphene buffer layer on the SiC(0001) interface by means of photoelectron spectroscopy, x-ray standing waves, and scanning tunneling microscopy. A coherent fraction close to unity proves the formation of a flat Pb monolayer on the SiC surface. An interlayer distance of 3.67 Å to the suspended graphene underlines the formation of a truly van der Waals heterostructure. The 2D Pb layer reveals a quasi ten-fold periodicity due to the formation of a grain boundary network, ensuring the saturation of the Si surface bonds. Moreover, the densely-packed Pb layer also efficiently minimizes the doping influence by the SiC substrate, both from the surface dangling bonds and the SiC surface polarization, giving rise to charge-neutral monolayer graphene. The observation of a long-ranged ((Formula presented.)) reconstruction on the graphene lattice at tunneling conditions close to Fermi energy is most likely a result of a nesting condition to be perfectly fulfilled.

KW - angle-resolved photoelectron sprectroscopy

KW - charge-neutral epitaxial graphene

KW - low energy electron diffraction

KW - normal incidence x-ray standing wave

KW - Pb monolayer intercalation

KW - scanning tunneling microscopy

KW - X-ray photoelectron spectroscopy

U2 - 10.1002/admi.202300471

DO - 10.1002/admi.202300471

M3 - Article

AN - SCOPUS:85165483522

SN - 2196-7350

VL - 10

JO - Advanced Materials Interfaces

JF - Advanced Materials Interfaces

IS - 27

ER -

Domain Boundary Formation Within an Intercalated Pb Monolayer Featuring Charge-Neutral Epitaxial Graphene

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